CN111687601A - One-blank drill traceability processing technology - Google Patents

Abstract

The invention provides a one-blank drill traceability processing technology, which comprises the following steps: s1: in a computer, two 3D diamond finished product models are designed according to the actual structural shape of a single diamond blank, a first identification code is designed at the interface position on the surface of the diamond blank corresponding to the two 3D diamond finished product models, and a second identification code is respectively designed at the tip position corresponding to the two 3D diamond finished product models; s2: according to the design, a first identification code, a second identification code, an edge line or a cutting positioning point for limiting the interface are engraved on the surface of the diamond blank by laser; s3: cutting the diamond blank along the interface of the two 3D diamond finished product models to obtain two semi-blanks; s4: processing the part of the semi-blank close to the boundary surface side to form a crown part and a girdle, and engraving the second identification code on the girdle by the laser; s5: and processing the unprocessed part of the semi-blank to form a tip part, thus obtaining the finished diamond product. The process is convenient for tracing with the same embryo drill, and avoids confusion.

Description

One-blank drill traceability processing technology

Technical Field

The invention relates to the technical field of diamond processing, in particular to a cogged diamond traceability processing technology.

Background

The homoembryo diamond is formed by processing the same diamond stone, and has special meaning and is loved by lovers. From the diamond stone to the diamond finished product, the whole processing circulation process, because the transport of diamond, the diamond confusion phenomenon appears easily, leads to easily using non-homoplastic diamond preparation homoplastic diamond product, finally takes place the deception consumer action of non-maliciousness, is unfavorable for keeping good reputation of enterprise.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the confusion of the same-embryo drill is avoided, and the one-embryo drill is used for processing the same-embryo drill products in percentage.

In order to solve the technical problems, the invention adopts the technical scheme that:

a one-blank drill traceability processing technology comprises the following steps:

s1: in a computer, two 3D diamond finished product models are designed according to the actual structural shape of a single diamond blank, the interface position of the diamond blank surface corresponding to the two 3D diamond finished product models is a first position, the tip positions corresponding to the two 3D diamond finished product models are a second position and a third position respectively, a first identification code is designed at the first position, and a second identification code is designed at the second position and the third position respectively.

S2: according to the design, the first identification code is engraved on the corresponding first position on the surface of the diamond blank by laser, the second identification code is engraved on the corresponding second position and third position respectively, and the edge line or cutting positioning point for limiting the interface is engraved on the surface of the diamond blank.

S3: and cutting the diamond blank along the interface of the two 3D diamond finished product models to obtain two semi-blanks.

S4: and processing the part of the semi-blank close to the boundary surface side to form a crown part and a girdle, and engraving the second identification code on the girdle by the laser.

S5: and processing the unprocessed part of the semi-blank to form a tip part, thus obtaining the finished diamond product.

Further, after the step S3 is executed, the first identification code is also cut into two parts, and a part of the first identification code is engraved on the surface of each of the half blanks.

Further, before executing the step S4, the first identification codes on the two semi-blanks are spliced, and it is checked whether the two semi-blanks are derived from the same diamond blank.

Further, the first identification code and the second identification code are the same identification code.

Further, before performing step S1, the shape, color and clarity of the diamond blank are observed.

Further, the wavelength of the laser is 1024 nm.

Further, the diamond blanks are octahedral gold body rough stones or dodecahedral gold body rough stones.

Further, the crown part, the girdle and the tip part are processed and formed by adopting a grinding mode

The invention has the beneficial effects that: through the mode of carving a plurality of identification codes on diamond blank, make diamond blank by cutting apart the back, the identification code that conveniently traces to the source is all carved with to two parts that obtain of cutting apart, and the cutting process of polishing remains throughout with the integrative identification code of diamond semi-manufactured goods, avoids the course of working to take place to obscure. And because the semi-finished diamond product is always engraved with the identification code, and the identification code is not easy to be damaged and fuzzy, the same-blank diamond is not easy to be confused even if the semi-finished diamond product is flexibly prepared in personnel, time and flow.

Drawings

The detailed structure of the invention is described in detail below with reference to the accompanying drawings

FIG. 1 is a diagram of a 3D diamond product model on a diamond blank of a cogged diamond traceability processing technique according to the present invention;

wherein 1-the first position, 2-the second position, 3-the third position.

Detailed Description

Example 1

Referring to fig. 1, a cogged drill traceability processing method includes the following steps:

s1: in a computer, two 3D diamond finished product models are designed according to the actual structural shape of a single diamond blank, the interface position of the diamond blank surface corresponding to the two 3D diamond finished product models is a first position 1, the tip positions corresponding to the two 3D diamond finished product models are a second position 2 and a third position 3 respectively, a first identification code is designed at the first position 1, and second identification codes are designed at the second position 2 and the third position 3 respectively.

S2: according to the design, the first identification code is engraved on the surface of the diamond blank at the corresponding first position 1 by laser, the second identification code is engraved at the corresponding second position 2 and third position 3 respectively, and the edge line or the cutting positioning point for limiting the interface is engraved on the surface of the diamond blank.

S3: cutting the diamond blank along the interface to obtain two half blanks.

S4: and processing the part of the semi-blank close to the boundary surface side to form a crown part and a girdle, and engraving the second identification code on the girdle by the laser.

S5: and processing the unprocessed part of the semi-blank to form a tip part, thus obtaining the finished diamond product.

Example 2

Referring to fig. 1, a cogged drill traceability processing method includes the following steps:

s1: firstly observing the body shape, color and clarity of the diamond blank, then designing two 3D diamond finished product models according to the actual structural shape of a single diamond blank in a computer, wherein the interface position of the diamond blank surface corresponding to the two 3D diamond finished product models is a first position 1, the tip positions corresponding to the two 3D diamond finished product models are a second position 2 and a third position 3 respectively, a first identification code is designed at the first position 1, and second identification codes are designed at the second position 2 and the third position 3 respectively. The first identification code is preferably formed by a simple figure or a combination of the simple figure and numbers or/and letters, and is convenient to quickly identify through a splicing mode.

S2: according to the design, a 1024nm laser is used for carving the first identification code on the surface of the diamond blank at the corresponding first position 1, respectively carving the second identification code at the corresponding second position 2 and third position 3, and also carving an edge line for limiting the interface on the surface of the diamond blank. The interface will divide the first identification code into two parts.

S3: cutting the diamond blank along the interface to obtain two half blanks. The first identification code is also cut into two parts, one part of the first identification code is carved on the surface of each semi-blank, and whether the two semi-blanks are identical or not can be quickly judged according to the line shape of the first identification code by splicing.

S4: the first identification codes on the two semi-blanks are firstly spliced, whether the two semi-blanks are derived from the same diamond blank is checked, then the two semi-blanks are placed on the same station for processing, and searching and checking are facilitated after processing. And processing the part of the semi-blank close to the boundary surface side to form a crown part and a girdle, and engraving the second identification code on the girdle by using 1024nm laser.

S5: and processing the unprocessed part of the semi-blank to form a tip part, thus obtaining the finished diamond product.

Example 3

Referring to fig. 1, a cogged drill traceability processing method includes the following steps:

s1: firstly observing the body shape, color and clarity of the diamond blank, then designing two 3D diamond finished product models according to the actual structural shape of a single diamond blank in a computer, wherein the interface position of the diamond blank surface corresponding to the two 3D diamond finished product models is a first position 1, the tip positions corresponding to the two 3D diamond finished product models are a second position 2 and a third position 3 respectively, a first identification code is designed at the first position 1, and second identification codes are designed at the second position 2 and the third position 3 respectively. The first identification code and the second identification code are the same identification code; the diamond blank is octahedral gold body or dodecahedral gold body.

S2: according to the design, 1024nm laser is used for carving the first identification code on the surface of the diamond blank at the corresponding first position 1, respectively carving the second identification code on the corresponding second position 2 and third position 3, and also carving a cutting positioning point for limiting the interface on the surface of the diamond blank. The interface will divide the first identification code into two parts.

S3: cutting the diamond blank along the interface to obtain two half blanks. The first identification code is also cut into two parts, and a part of the first identification code is engraved on the surface of each semi-blank.

S4: the first identification codes on the two semi-blanks are firstly spliced, whether the two semi-blanks are derived from the same diamond blank is checked, then the two semi-blanks are placed on the same station for processing, and searching and checking are facilitated after processing. And grinding the part of the semi-blank close to the boundary surface side to form a crown part and a girdle, and engraving the second identification code on the girdle by using 1024nm laser.

S5: and grinding the unprocessed part of the semi-blank to form a tip part, thus obtaining the finished diamond product.

In summary, according to the one-blank drill traceability processing technology provided by the invention, the manner of engraving the plurality of identification codes on the diamond blank is adopted, so that after the diamond blank is divided, the identification codes convenient to trace to the source are engraved on two divided parts, and the identification codes integrated with the semi-finished diamond product are always reserved in the grinding and cutting process, thereby avoiding confusion in the processing process. And because the semi-finished diamond product is always engraved with the identification code, and the identification code is not easy to be damaged and fuzzy, the same-blank diamond is not easy to be confused even if the semi-finished diamond product is flexibly prepared in personnel, time and flow. The processing process is checked for many times, so that the phenomenon of mixing of the same blank drill is further ensured not to occur.

The first … … and the second … … are only used for name differentiation and do not represent how different the importance and position of the two are.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. The same-embryo drill traceability processing technology is characterized by comprising the following steps of:

s1: in a computer, designing two 3D diamond finished product models according to the actual structure shape of a single diamond blank, wherein the interface position on the surface of the diamond blank corresponding to the two 3D diamond finished product models is a first position, the tip positions corresponding to the two 3D diamond finished product models are respectively a second position and a third position, a first identification code is designed at the first position, and second identification codes are respectively designed at the second position and the third position;

s2: according to the design, the first identification code is engraved on the corresponding first position on the surface of the diamond blank by laser, the second identification code is engraved on the corresponding second position and third position respectively, and an edge line or a cutting positioning point for limiting the interface is engraved on the surface of the diamond blank;

s3: cutting the diamond blank along the interface to obtain two semi-blanks;

s4: processing the part of the semi-blank close to the boundary surface side to form a crown part and a girdle, and engraving the second identification code on the girdle by the laser;

s5: and processing the unprocessed part of the semi-blank to form a tip part, thus obtaining the finished diamond product.

2. The method according to claim 1, wherein after the step S3, the first identification code is cut into two parts, and a portion of the first identification code is engraved on the surface of each of the semi-blanks.

3. The method of claim 2, wherein the first identification codes of the two semi-blanks are combined to check whether the two semi-blanks are derived from the same diamond blank before performing step S4.

4. The consubstantial drill traceability processing method of any one of claims 1 to 3, wherein the first identification code and the second identification code are the same identification code.

5. The method of claim 4, wherein said diamond blank is observed for shape, color and clarity before said step S1 is executed.

6. The isoembryo drill traceability processing technique of claim 5, wherein the laser has a wavelength of 1024 nm.

7. The isoembryo diamond traceability process of claim 6, wherein the diamond blank is octahedral rhombohedral boulder or dodecahedral rhombohedral boulder.

8. The isogenous drill traceability process of claim 7, wherein said crown portion, said girdle and said tip portion are formed by sanding.

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