CN110468298B - Method for preparing light blue gold alloy for jewelry and clock industry - Google Patents

Abstract

The invention discloses a preparation method of light blue gold alloy for jewelry and clock industries, which comprises the following steps: collecting alloy components and process information by a mobile terminal; the method comprises the steps that a mobile terminal sends alloy component and process information uploading request messages to a plurality of base stations; receiving, by the mobile terminal, a transmission permission message transmitted by one or more base stations; if the mobile terminal receives a message which is sent by a base station and allowed to be sent, the mobile terminal analyzes the message which is allowed to be sent so as to judge the number of uplink carriers which are distributed to the mobile terminal by the base station; if the base station is judged to distribute an uplink carrier for the mobile terminal, the mobile terminal sends alloy components and process information to the base station on the uplink carrier; if the base station is judged to distribute a plurality of uplink carriers for the mobile terminal, the mobile terminal further determines the priority of the plurality of uplink carriers; the alloy composition and process information are sent by the mobile terminal to the base station on a plurality of uplink carriers in sequence.

Description

Method for preparing light blue gold alloy for jewelry and clock industry

Technical Field

The invention relates to the field of metal alloys, in particular to a preparation method of light blue gold alloy used in the jewelry and clock industries.

Background

Gold was first regarded as important as a material for jewelry and decoration. With the development of the times and the improvement of the living standard of people, the aesthetic concept of people is continuously improved, and the noble metal jewelry is more and more favored by consumers. Pure gold is too soft and has only one color (yellow), so that the color is too monotonous in artistic expression, and jewelry with various colors and different gold contents is produced. Although the jewelry industry in China, particularly the jewelry alloy, develops rapidly, the starting point is low due to late start, and the difference from the international level is large in some technical links. The industrial problem is not solved for a long time, the market sales volume and the use experience of related products are influenced, and the market occupation of the products in the international field is also severely limited. The gold content is usually measured by the international K-site system according to the different gold contents, so that gold alloys are also called K-gold, and the K-number/24 is the gold content, for example 18K, 18/24 ═ 0.75, i.e. 75% gold content for 18K gold and 25% other alloying elements. With the validation of the UNI EN 1811 standard, the use of K gold in nickel elements is limited. Meanwhile, due to the effectiveness of the 'Dode-Frank' method, the tin element is also regulated and controlled. The market demands for K gold ornaments are diversified (particularly, colors), and more mature are K red gold alloys, K yellow gold alloys and K white gold alloys. CN 102676864 a reports the formulation and preparation method of purple K gold, and CN 107208186A reports the master alloy used for manufacturing platinum alloy.

The information disclosed in this background section is only for enhancement of understanding of the general background of the invention and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person skilled in the art.

Disclosure of Invention

The object of the present invention is to provide a method for the preparation of light blue gold alloys for the jewellery and watch industry, which overcomes the disadvantages of the prior art.

In order to achieve the above object, the present invention provides a method for preparing light blue gold alloy for jewelry and clock industry, comprising the steps of: collecting alloy components and process information by a mobile terminal; the method comprises the steps that a mobile terminal sends alloy component and process information uploading request messages to a plurality of base stations; receiving, by the mobile terminal, a transmission permission message transmitted by one or more base stations, wherein the transmission permission message is transmitted by the base stations in response to receiving the alloy component and process information upload request message; if the mobile terminal receives a message which is sent by a base station and allowed to be sent, the mobile terminal analyzes the message which is allowed to be sent so as to judge the number of uplink carriers which are distributed to the mobile terminal by the base station; if the mobile terminal judges that the base station distributes an uplink carrier to the mobile terminal, the mobile terminal sends alloy components and process information to the base station on the uplink carrier; if the mobile terminal judges that the base station distributes a plurality of uplink carriers to the mobile terminal, the mobile terminal further determines the priority of the plurality of uplink carriers; the method comprises the steps that a mobile terminal sends alloy components and process information to a base station on a plurality of uplink carriers in sequence according to the priorities of the plurality of uplink carriers; if the mobile terminal receives the transmission permission message sent by the base stations, the mobile terminal analyzes the transmission permission message to judge the priority of the uplink carrier distributed to the mobile terminal by the base stations; and the mobile terminal sends the alloy components and the process information to the base stations on the uplink carriers in sequence according to the priorities of the uplink carriers allocated to the mobile terminal by the base stations.

In a preferred embodiment, the step of sequentially sending the alloy component and the process information to the base station on a plurality of uplink carriers by the mobile terminal according to the priorities of the plurality of uplink carriers comprises the following steps: transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, then the portion of the alloy composition and process information is sent by the mobile terminal to the base station on an uplink carrier having a third priority.

In a preferred embodiment, the plurality of base stations at least include a first base station and a second base station, and the step of sending the alloy components and the process information to the plurality of base stations by the mobile terminal on the plurality of uplink carriers in sequence according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations includes the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a second priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a third priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the second base station on an uplink carrier having a third priority.

In a preferred embodiment, the step of sending the alloy components and the process information to the plurality of base stations on the plurality of uplink carriers in sequence by the mobile terminal according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations further comprises the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a third priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a second priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and the process information to the second base station on an uplink carrier having a second priority while notifying, by the mobile terminal, the second base station of a priority violation notification; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a third priority.

In a preferred embodiment, the alloy composition comprises, inter alia: 5-10 wt% of silver, 5-7.5 wt% of copper, 1-5 wt% of zinc, 1-10 wt% of indium, 4-10 wt% of manganese, 80-120ppm of iridium, 80-120ppm of boron, 30-50ppm of phosphorus and the balance of gold.

The invention also provides a system for preparing a light blue gold alloy for the jewelry and clock industries, comprising: a unit for collecting alloy components and process information by a mobile terminal; a unit for transmitting alloy component and process information upload request messages to a plurality of base stations by a mobile terminal; means for receiving, by a mobile terminal, a clear to send message sent by one or more base stations, wherein the clear to send message is sent by a base station in response to receiving an alloy component and process information upload request message; a unit for analyzing, by the mobile terminal, the transmission permission message to determine the number of uplink carriers allocated by the base station to the mobile terminal if the mobile terminal receives the transmission permission message transmitted by one base station; a unit for transmitting alloy components and process information to the base station by the mobile terminal on an uplink carrier if the mobile terminal determines that the base station allocates the uplink carrier to the mobile terminal; means for further determining, by the mobile terminal, a priority of the plurality of uplink carriers if the mobile terminal determines that the base station allocates the plurality of uplink carriers to the mobile terminal; means for transmitting, by the mobile terminal, alloy components and process information to the base station on the plurality of uplink carriers in sequence according to priorities of the plurality of uplink carriers; means for parsing, by the mobile terminal, the clear-to-send message to determine a priority of an uplink carrier allocated to the mobile terminal by the plurality of base stations if the mobile terminal receives the clear-to-send message sent by the plurality of base stations; and means for transmitting, by the mobile terminal, the alloy component and the process information to the plurality of base stations on the plurality of uplink carriers in sequence according to priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations.

In a preferred embodiment, the step of sequentially sending the alloy component and the process information to the base station on a plurality of uplink carriers by the mobile terminal according to the priorities of the plurality of uplink carriers comprises the following steps: transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, then the portion of the alloy composition and process information is sent by the mobile terminal to the base station on an uplink carrier having a third priority.

In a preferred embodiment, the plurality of base stations at least include a first base station and a second base station, and the step of sending the alloy components and the process information to the plurality of base stations by the mobile terminal on the plurality of uplink carriers in sequence according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations includes the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a second priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a third priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the second base station on an uplink carrier having a third priority.

In a preferred embodiment, the step of sending the alloy components and the process information to the plurality of base stations on the plurality of uplink carriers in sequence by the mobile terminal according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations further comprises the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a third priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a second priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and the process information to the second base station on an uplink carrier having a second priority while notifying, by the mobile terminal, the second base station of a priority violation notification; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a third priority.

In a preferred embodiment, the alloy composition comprises, inter alia: 5-10 wt% of silver, 5-7.5 wt% of copper, 1-5 wt% of zinc, 1-10 wt% of indium, 4-10 wt% of manganese, 80-120ppm of iridium, 80-120ppm of boron, 30-50ppm of phosphorus and the balance of gold.

Compared with the prior art, the invention has the following advantages: the traditional jewelry gold process mostly adopts a method of manually preparing metal and making, the subjective randomness of the method is relatively large, although each factory has a strict operation rule, the product quality and the color quality basically depend on the experience of a master worker, the operation proficiency, even the working state of the master worker at that time, and other factors. Meanwhile, customers (especially big customers who like to collect) have very high requirements on the color, luster, texture, quality and the like of jewelry gold, so even a slight difference in the time of the heat treatment converter process can cause a visible difference in the color and luster of jewelry gold products. In addition, the cost of the experienced master is typically very high, which results in a high cost of jewelry metalworking. In order to solve the problems, improve the quality stability of jewelry gold and reduce the manufacturing cost of jewelry gold, the invention provides an automatic preparation method of light blue gold alloy for jewelry and clock industries.

Drawings

FIG. 1 is a flow chart of a method of making a light blue gold alloy for use in the jewelry and watch industry according to one embodiment of the present invention.

FIG. 2 is an SEM photograph of a product of example 1 according to the invention.

FIG. 3 is an SEM photograph of a product of example 2 according to the invention.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying drawings, but it should be understood that the scope of the present invention is not limited to the specific embodiments.

Throughout the specification and claims, unless explicitly stated otherwise, the word "comprise", or variations such as "comprises" or "comprising", will be understood to imply the inclusion of a stated element or component but not the exclusion of any other element or component.

FIG. 1 is a flow chart of a method of making a light blue gold alloy for use in the jewelry and watch industry according to one embodiment of the present invention. As shown in the figure, the preparation method comprises the following steps:

step 101: collecting alloy components and process information (the process information comprises information of a heat treatment process, a smelting process and the like) by a mobile terminal;

step 102: the method comprises the steps that a mobile terminal sends alloy component and process information uploading request messages to a plurality of base stations;

step 103: receiving, by the mobile terminal, a transmission permission message transmitted by one or more base stations, wherein the transmission permission message is transmitted by the base stations in response to receiving the alloy component and process information upload request message;

step 104: if the mobile terminal receives a message which is sent by a base station and allowed to be sent, the mobile terminal analyzes the message which is allowed to be sent so as to judge the number of uplink carriers which are distributed to the mobile terminal by the base station;

step 105: if the mobile terminal judges that the base station distributes an uplink carrier to the mobile terminal, the mobile terminal sends alloy components and process information to the base station on the uplink carrier;

step 106: if the mobile terminal judges that the base station distributes a plurality of uplink carriers to the mobile terminal, the mobile terminal further determines the priority of the plurality of uplink carriers;

step 107: the method comprises the steps that a mobile terminal sends alloy components and process information to a base station on a plurality of uplink carriers in sequence according to the priorities of the plurality of uplink carriers;

step 108: if the mobile terminal receives the transmission permission message sent by the base stations, the mobile terminal analyzes the transmission permission message to judge the priority of the uplink carrier distributed to the mobile terminal by the base stations; and

step 109: the method comprises the steps that a mobile terminal sends alloy components and process information to a plurality of base stations on the plurality of uplink carriers in sequence according to priorities of the uplink carriers distributed to the mobile terminal by the plurality of base stations (after the base stations receive the alloy components and the process information, the base stations transmit the information to one side of a core network, and then the core network transmits related information to a production factory through the Internet, wherein the production factory can be an intelligent factory, and most of operations can be performed by automatic equipment).

In a preferred embodiment, the step of sequentially sending the alloy component and the process information to the base station on a plurality of uplink carriers by the mobile terminal according to the priorities of the plurality of uplink carriers comprises the following steps: transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, then the portion of the alloy composition and process information is sent by the mobile terminal to the base station on an uplink carrier having a third priority.

In a preferred embodiment, the plurality of base stations at least include a first base station and a second base station, and the step of sending the alloy components and the process information to the plurality of base stations by the mobile terminal on the plurality of uplink carriers in sequence according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations includes the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a second priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a third priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the second base station on an uplink carrier having a third priority.

In a preferred embodiment, the step of sending the alloy components and the process information to the plurality of base stations on the plurality of uplink carriers in sequence by the mobile terminal according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations further comprises the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a third priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a second priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and the process information to the second base station on an uplink carrier having a second priority while notifying, by the mobile terminal, the second base station of a priority violation notification; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a third priority.

The invention also provides a system for preparing a light blue gold alloy for the jewelry and clock industries, comprising: a unit for collecting alloy components and process information by a mobile terminal; a unit for transmitting alloy component and process information upload request messages to a plurality of base stations by a mobile terminal; means for receiving, by a mobile terminal, a clear to send message sent by one or more base stations, wherein the clear to send message is sent by a base station in response to receiving an alloy component and process information upload request message; a unit for analyzing, by the mobile terminal, the transmission permission message to determine the number of uplink carriers allocated by the base station to the mobile terminal if the mobile terminal receives the transmission permission message transmitted by one base station; a unit for transmitting alloy components and process information to the base station by the mobile terminal on an uplink carrier if the mobile terminal determines that the base station allocates the uplink carrier to the mobile terminal; means for further determining, by the mobile terminal, a priority of the plurality of uplink carriers if the mobile terminal determines that the base station allocates the plurality of uplink carriers to the mobile terminal; means for transmitting, by the mobile terminal, alloy components and process information to the base station on the plurality of uplink carriers in sequence according to priorities of the plurality of uplink carriers; means for parsing, by the mobile terminal, the clear-to-send message to determine a priority of an uplink carrier allocated to the mobile terminal by the plurality of base stations if the mobile terminal receives the clear-to-send message sent by the plurality of base stations; and means for transmitting, by the mobile terminal, the alloy component and the process information to the plurality of base stations on the plurality of uplink carriers in sequence according to priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations.

In a preferred embodiment, the step of sequentially sending the alloy component and the process information to the base station on a plurality of uplink carriers by the mobile terminal according to the priorities of the plurality of uplink carriers comprises the following steps: transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, then the portion of the alloy composition and process information is sent by the mobile terminal to the base station on an uplink carrier having a third priority.

In a preferred embodiment, the plurality of base stations at least include a first base station and a second base station, and the step of sending the alloy components and the process information to the plurality of base stations by the mobile terminal on the plurality of uplink carriers in sequence according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations includes the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a second priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a third priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a second priority; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the second base station on an uplink carrier having a third priority.

In a preferred embodiment, the step of sending the alloy components and the process information to the plurality of base stations on the plurality of uplink carriers in sequence by the mobile terminal according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations further comprises the following steps: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a third priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a second priority and a fourth priority, the mobile terminal sends part of the alloy component and the process information to the first base station on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of the alloy composition and the process information to the second base station on an uplink carrier having a second priority while notifying, by the mobile terminal, the second base station of a priority violation notification; if there is still a portion of the alloy composition and process information to send, sending, by the mobile terminal, a portion of the alloy composition and process information to the first base station on an uplink carrier having a third priority.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or mobile terminal program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a mobile terminal program product embodied on one or more mobile terminal-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having mobile terminal-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and mobile terminal program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by mobile terminal program instructions. These mobile terminal program instructions may be provided to a processor of a general purpose mobile terminal, special purpose mobile terminal, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the mobile terminal or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These mobile terminal program instructions may also be stored in a mobile terminal-readable memory that can direct a mobile terminal or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the mobile terminal-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These mobile terminal program instructions may also be loaded onto a mobile terminal or other programmable data processing apparatus to cause a series of operational steps to be performed on the mobile terminal or other programmable apparatus to produce a mobile terminal implemented process such that the instructions which execute on the mobile terminal or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

The operation of the alloy manufacturing platform and various embodiments of the present invention are described below after the alloy manufacturing platform receives the alloy composition and process information.

Example 1

The alloy manufacturing platform is prepared from 5% of silver (Ag), 5% of copper (Cu), 1% of zinc (Zn), 1% of indium (In), 4% of manganese (Mn) and the balance of Au by weight percentage. Smelting under the protection of inert gas or reducing gas, wherein the smelting temperature is 1000 ℃. And (3) reversing the mould according to a method known in the jewelry industry and the clock industry, and then carrying out subsequent treatment such as grinding, polishing and the like to obtain the 18K light blue gold alloy ornament. Ten sets of samples were obtained by repeating the above process, and the obtained 18K light blue gold alloy CIELab color data a: -1.5, b: 2-2 (i.e., the ten sets of samples were completely consistent in color within the detection limits of the instrument), and exhibited a bluish color with a hardness Hv of 180-182. The average manufacturing cost is 1 (since the actual cost value relates to the applicant's trade secret, and moreover the specific value of the cost itself has no effect on the explanation of the problem, the average cost values are normalized to the actual cost of example 1). The alloy has good casting performance, and fine die cavities can be well filled in the process of reverse die (casting) in the jewelry and clock industries. The tendency to produce sand holes (casting porosity) is small.

Example 2

The alloy manufacturing platform is prepared from the following components In percentage by weight, 10% of silver (Ag), 7.5% of copper (Cu), 5% of zinc (Zn), 10% of indium (In), 10% of manganese (Mn), 120ppm of iridium (Ir), 120ppm of boron (B), 50ppm of phosphorus (P) and the balance of Au. Smelting under the protection of inert gas or reducing gas, wherein the smelting temperature is 1100 ℃. And (3) reversing the mould according to a method known in the jewelry industry and the clock industry, and then carrying out subsequent treatment such as grinding, polishing and the like to obtain the 18K light blue gold alloy ornament. Ten sets of samples were obtained by repeating the above process, and the obtained 18K light blue gold alloy CIELab color data a: 1.5-1.5, b: 8-8, and Hv 230-235. The average value of the manufacturing cost is 1.1, the alloy has good casting performance, and fine die cavities can be well filled in the process of reverse die (casting) in the jewelry and clock industries. The tendency to produce sand holes (casting porosity) is small.

Example 3

The alloy manufacturing platform is prepared from the following components In percentage by weight, wherein the content of silver (Ag) is 7.5%, the content of copper (Cu) is 6.5%, the content of zinc (Zn) is 3.5%, the content of indium (In) is 5%, the content of manganese (Mn) is 7%, the content of iridium (Ir) is 120ppm, the content of boron (B) is 120ppm, the content of phosphorus (P) is 50ppm, and the balance is Au. Smelting under the protection of inert gas or reducing gas, wherein the smelting temperature is 1050 ℃. And (3) reversing the mould according to a method known in the jewelry industry and the clock industry, and then carrying out subsequent treatment such as grinding, polishing and the like to obtain the 18K light blue gold alloy ornament. Ten sets of samples were obtained by repeating the above process, and the obtained 18K light blue gold alloy CIELab color data a: 0.5-0.5, b: 5-5, and Hv 210-213. The average value of the manufacturing cost is 1.1, the alloy has good casting performance, and fine die cavities can be well filled in the process of reverse die (casting) in the jewelry and clock industries. The tendency to produce sand holes (casting porosity) is small.

Comparative example 1

Instead of using the methods described herein, the fabrication is performed using conventional manual fabrication methods. The alloy manufacturing platform is prepared from 5% of silver (Ag), 5% of copper (Cu), 1% of zinc (Zn), 1% of indium (In), 4% of manganese (Mn) and the balance of Au by weight percentage. Smelting under the protection of inert gas or reducing gas, wherein the smelting temperature is 1000 ℃. And (3) reversing the mould according to a method known in the jewelry industry and the clock industry, and then carrying out subsequent treatment such as grinding, polishing and the like to obtain the 18K light blue gold alloy ornament. Ten sets of samples are obtained by repeating the process, and the obtained 18K light blue gold alloy CIELab color data a is-1.5 to-0.5, b is: 2-2.5, light blue and hardness Hv of 180-195. The average manufacturing cost is 1.8.

Comparative example 2

Instead of using the methods described herein, the fabrication is performed using conventional manual fabrication methods. The alloy manufacturing platform is prepared from the following components In percentage by weight, wherein the content of silver (Ag) is 7.5%, the content of copper (Cu) is 6.5%, the content of zinc (Zn) is 3.5%, the content of indium (In) is 5%, the content of manganese (Mn) is 7%, the content of iridium (Ir) is 120ppm, the content of boron (B) is 120ppm, the content of phosphorus (P) is 50ppm, and the balance is Au. Smelting under the protection of inert gas or reducing gas, wherein the smelting temperature is 1050 ℃. And (3) reversing the mould according to a method known in the jewelry industry and the clock industry, and then carrying out subsequent treatment such as grinding, polishing and the like to obtain the 18K light blue gold alloy ornament. Ten sets of samples were obtained by repeating the above process, and the obtained 18K light blue gold alloy CIELab color data a: 0.5-0.9, b: 5-5.9, and Hv 210-237. The average manufacturing cost is 1.8.

The foregoing descriptions of specific exemplary embodiments of the present invention have been presented for purposes of illustration and description. It is not intended to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain certain principles of the invention and its practical application to enable one skilled in the art to make and use various exemplary embodiments of the invention and various alternatives and modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims and their equivalents.

Claims (2)

1. A method for preparing light blue gold alloy used in jewelry and clock industry is characterized in that: the preparation method of the light blue gold alloy for the jewelry and clock industry comprises the following steps: collecting alloy components and process information by a mobile terminal; the mobile terminal sends alloy component and process information uploading request information to a plurality of base stations; receiving, by the mobile terminal, a clear to send message sent by one or more base stations, wherein the clear to send message is sent by a base station in response to receiving the alloy component and process information upload request message; if the mobile terminal receives a message which is sent by a base station and allowed to be sent, the mobile terminal analyzes the message which is allowed to be sent so as to judge the number of uplink carriers distributed to the mobile terminal by the base station; if the mobile terminal judges that the base station distributes an uplink carrier to the mobile terminal, the mobile terminal sends alloy components and process information to the base station on the uplink carrier; if the mobile terminal judges that the base station distributes a plurality of uplink carriers to the mobile terminal, the mobile terminal further determines the priority of the plurality of uplink carriers; the mobile terminal sends alloy components and process information to the base station on a plurality of uplink carriers in sequence according to the priorities of the plurality of uplink carriers; if the mobile terminal receives the transmission permission message sent by a plurality of base stations, the mobile terminal analyzes the transmission permission message to judge the priority of uplink carriers distributed to the mobile terminal by the plurality of base stations; and the mobile terminal sends the alloy components and the process information to the plurality of base stations on the plurality of uplink carriers in sequence according to the priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations, and the mobile terminal sends the alloy components and the process information to the base stations on the plurality of uplink carriers in sequence according to the priorities of the plurality of uplink carriers comprises the following steps: transmitting, by the mobile terminal, a portion of alloy composition and process information to the base station on an uplink carrier having a first priority; transmitting, by the mobile terminal, a portion of alloy composition and process information to the base station on an uplink carrier having a second priority; if there is still a part of the alloy component and process information to be transmitted, transmitting, by the mobile terminal, a part of the alloy component and process information to the base stations on an uplink carrier with a third priority, the plurality of base stations including at least a first base station and a second base station, and transmitting, by the mobile terminal, the alloy component and process information to the plurality of base stations on the plurality of uplink carriers in sequence according to priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations, comprising the steps of: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a second priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a third priority and a fourth priority, the alloy component and a part of the process information are sent to the first base station by the mobile terminal on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of alloy composition and process information to the first base station on an uplink carrier having a second priority; transmitting, by the mobile terminal, a portion of the alloy component and process information to the second base station on an uplink carrier having a third priority if there is still a portion of the alloy component and process information to be transmitted, the transmitting, by the mobile terminal, the alloy component and process information to the plurality of base stations on the plurality of uplink carriers in sequence according to priorities of the uplink carriers assigned to the mobile terminal by the plurality of base stations further comprising the steps of: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a third priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a second priority and a fourth priority, the alloy component and a part of the process information are sent to the first base station by the mobile terminal on the uplink carrier with the first priority; transmitting, by the mobile terminal, a portion of alloy composition and process information to the second base station on an uplink carrier having a second priority while notifying, by the mobile terminal, the second base station of a priority violation notification; if there is still a part of alloy composition and process information to be transmitted, transmitting a part of the alloy composition and process information to the first base station by the mobile terminal on an uplink carrier with a third priority, transmitting the information to the core network side by the base station after the base station receives the alloy composition and process information, and transmitting the relevant information to the production plant by the core network through the internet, wherein the alloy composition comprises: 7.5 wt% of silver, 6.5 wt% of copper, 3.5 wt% of zinc, 5 wt% of indium, 7 wt% of manganese, 120ppm of iridium, 120ppm of boron, 50ppm of phosphorus, and the balance of gold.

2. A system for preparing light blue gold alloys for the jewelry and clock industries, characterized in that: the preparation system of light blue gold alloy for jewelry and clock industries comprises: a unit for collecting alloy components and process information by a mobile terminal; means for transmitting, by the mobile terminal, alloy component and process information upload request messages to a plurality of base stations; means for receiving, by the mobile terminal, a clear to send message sent by one or more base stations, wherein the clear to send message is sent by a base station in response to receiving the alloy component and process information upload request message; a unit configured to, if the mobile terminal receives a transmission permission message sent by a base station, parse, by the mobile terminal, the transmission permission message to determine the number of uplink carriers allocated by the base station to the mobile terminal; means for sending, by the mobile terminal, alloy components and process information to the base station on an uplink carrier if the mobile terminal determines that the base station allocates the one uplink carrier to the mobile terminal; means for further determining, by the mobile terminal, a priority of a plurality of uplink carriers if the mobile terminal determines that the base station allocates the plurality of uplink carriers to the mobile terminal; means for transmitting, by the mobile terminal, alloy components and process information to the base station on a plurality of uplink carriers in sequence according to priorities of the plurality of uplink carriers; means for parsing, by the mobile terminal, a transmission permission message sent by a plurality of base stations to determine a priority of an uplink carrier allocated to the mobile terminal by the plurality of base stations if the mobile terminal receives the transmission permission message; and a unit configured to sequentially transmit, by the mobile terminal, the alloy component and the process information to the plurality of base stations on the plurality of uplink carriers according to priorities of uplink carriers allocated to the mobile terminal by the plurality of base stations, wherein the step of sequentially transmitting, by the mobile terminal, the alloy component and the process information to the base stations on the plurality of uplink carriers according to the priorities of the plurality of uplink carriers includes: transmitting, by the mobile terminal, a portion of alloy composition and process information to the base station on an uplink carrier having a first priority; transmitting, by the mobile terminal, a portion of alloy composition and process information to the base station on an uplink carrier having a second priority; if there is still a part of the alloy component and process information to be transmitted, transmitting, by the mobile terminal, a part of the alloy component and process information to the base stations on an uplink carrier with a third priority, the plurality of base stations including at least a first base station and a second base station, and transmitting, by the mobile terminal, the alloy component and process information to the plurality of base stations on the plurality of uplink carriers in sequence according to priorities of the uplink carriers allocated to the mobile terminal by the plurality of base stations, comprising the steps of: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a second priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a third priority and a fourth priority, the alloy component and a part of the process information are sent to the first base station by the mobile terminal on the uplink carriers with the first priority; transmitting, by the mobile terminal, a portion of alloy composition and process information to the first base station on an uplink carrier having a second priority; transmitting, by the mobile terminal, a portion of the alloy component and process information to the second base station on an uplink carrier having a third priority if there is still a portion of the alloy component and process information to be transmitted, the transmitting, by the mobile terminal, the alloy component and process information to the plurality of base stations on the plurality of uplink carriers in sequence according to priorities of the uplink carriers assigned to the mobile terminal by the plurality of base stations further comprising the steps of: if the mobile terminal judges that the first base station allocates two uplink carriers to the mobile terminal, the second base station allocates two uplink carriers to the mobile terminal, the two uplink carriers allocated to the mobile terminal by the first base station have a first priority and a third priority, and the two uplink carriers allocated to the mobile terminal by the second base station have a second priority and a fourth priority, the alloy component and a part of the process information are sent to the first base station by the mobile terminal on the uplink carrier with the first priority; transmitting, by the mobile terminal, a portion of alloy composition and process information to the second base station on an uplink carrier having a second priority while notifying, by the mobile terminal, the second base station of a priority violation notification; if there is still a part of alloy composition and process information to be transmitted, transmitting a part of the alloy composition and process information to the first base station by the mobile terminal on an uplink carrier with a third priority, transmitting the information to the core network side by the base station after the base station receives the alloy composition and process information, and transmitting the relevant information to the production plant by the core network through the internet, wherein the alloy composition comprises: 7.5 wt% of silver, 6.5 wt% of copper, 3.5 wt% of zinc, 5 wt% of indium, 7 wt% of manganese, 120ppm of iridium, 120ppm of boron, 50ppm of phosphorus, and the balance of gold.

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