KR101522159B1 - Manufacturing method of gold bar or silver bar - Google Patents

Abstract

The present invention provides a method of manufacturing a gold bar or a silver bar which is capable of engraving sophisticated characters or patterns and has various colors through color printing. A method of manufacturing a gold bar or a silver bar according to an embodiment of the present invention includes casting a first semi-finished product from a raw material of gold or silver, washing the first semi-finished product, A step of removing the burrs from the surface of the second semi-finished product, a step of heat-treating the second semi-finished product, a step of washing the second semi-finished product, A step of forming a third semi-finished product by charging the second semi-finished product which has been subjected to the buffing treatment in a mold and then pressing the surface of the third semi-finished product; and engraving the surface of the third semi-finished product. Further, the method of manufacturing a gold bar or a silver bar may further include the step of color printing the surface of the third semi-finished product after the stamping step, wherein the surface of the third semi-finished product is coated Further comprising the steps of:

Description

TECHNICAL FIELD [0001] The present invention relates to a manufacturing method of a gold bar or a silver bar,

The present invention relates to a method of manufacturing a bar using a noble metal, and more particularly to a method of manufacturing a gold bar or a silver bar.

Gold or silver is a typical precious metal used to make jewelry. Gold or silver is traded or stocked in various shapes other than jewelry. An example of such a product is a gold bar in the form of a bar (hereinafter, referred to as 'gold bar') or a silver bar (hereinafter referred to as 'silver bar').

Conventionally, a casting method is used in which gold or silver is melted to prepare a gold bar or a silver bar, and then the molten gold is poured into a mold to cool it. However, the gold bars or silver bars manufactured by the conventional casting method have a problem that the surface is rough, has almost no gloss, and bubble marks are formed on the surface. On the surface of the gold bar or the silver bar, letters or patterns representing purity, mass, manufacturer, etc. are formed. For this purpose, in the conventional casting method, shapes corresponding to letters and patterns have been prepared in the mold in advance. Therefore, when the design of the gold bar or the silver bar is varied by changing the character or the pattern, there is a burden to newly build the template. In addition, gold bars or silver bars made of high purity gold or silver have a soft surface, so that characters and patterns that can be represented by the template are limited.

In this connection, an example of a method of manufacturing a gold bar or a silver bar according to the prior art is disclosed in Korean Patent Registration No. 10-1278658. According to this document, a basic bar is made by a casting method to produce a gold bar or a silver bar, and a card-shaped bar is produced by a rolling method. Then, the card-shaped bar is pressed and attached to the upper surface and the lower surface of the basic bar.

Korean Patent Registration No. 10-1278658

However, in the case of the gold bar or silver bar manufacturing method according to the related art, the basic bar and the card-shaped bar must be manufactured by separate processes. Then, the basic type bar and the card type bar must be pressed back at a high temperature and a high pressure. Therefore, the process of manufacturing a gold bar or a silver bar is troublesome and complicated. In addition to the casting apparatus for making the basic bar, there is a burden of having an expensive rolling apparatus for forming a card-shaped bar, for example, a roller apparatus. In addition, even if a rolling type card-shaped bar is employed, gold bars or silver bars made of high purity gold or silver do not have hardened surfaces. Therefore, it is difficult to diversify designs of gold bars or silver bars because they can not imprint elaborate characters or patterns. In addition, since gold bars or silver bars exhibit colors only with the inherent color of the metal, there is a limit to improving the aesthetics, and it is difficult to have product differentiation.

Disclosure of Invention Technical Problem [8] The present invention provides a method for manufacturing a gold bar or a silver bar capable of displaying sophisticated characters or patterns. Further, the present invention provides a method of manufacturing a gold bar or a silver bar to which various colors are imparted by color printing.

A method of manufacturing a gold bar or a silver bar according to an embodiment of the present invention includes casting a first semi-finished product from a raw material of gold or silver, washing the first semi-finished product, A step of removing the burrs from the surface of the second semi-finished product, a step of heat-treating the second semi-finished product, a step of washing the second semi-finished product, A step of forming a third semi-finished product by charging the second semi-finished product which has been subjected to the buffing treatment in a mold and then pressing the surface of the third semi-finished product; and engraving the surface of the third semi-finished product.

In an embodiment, the method of manufacturing a gold bar or a silver bar further comprises color printing the surface of the third semi-finished product after the stamping step, wherein after the stamping step or the color printing step, And a step of coating the surface. In addition, the method of manufacturing a gold bar or a silver bar may further include packaging the third semi-finished product after the coating process.

In an embodiment, the gold or silver raw material has a purity of at least 99.99%.

In an embodiment, in the casting of the first semi-finished product, the first semi-finished product is separated from the mold at a temperature range of 650 to 750 캜 and kept at room temperature.

In the embodiment, in the casting step, the raw material is melted using a crucible in which a ceramic cylinder, a carbon cylinder and a boron nitride cylinder are sequentially stacked.

The cleaning of the first semi-finished product may include a first cleaning step of oxidizing and removing foreign substances from the surface of the first semi-finished product, a second cleaning step of cleaning the surface of the first semi-finished product using a wet tumbling device, . Further, in the first cleaning step, the first semi-finished product is immersed in a cleaning solution, and the cleaning solution is an aqueous hydrogen peroxide solution.

In the embodiment, the step of forming into the second semi-finished product includes heating the surface of the first semi-finished product, pressing the heated first semi-finished product, and cooling the first semi-finished product to room temperature .

In the embodiment, in the heat treatment step, the second semi-finished product is heated to 550 to 650 ° C and quenched.

In an embodiment, the buffing treatment step includes polishing the washed second semi-finished product using a buffing device, and washing the second semi-finished product using a steam washer.

In an embodiment, in the molding step with the third semi-finished product, a surface is lapped and a chromium-plated mold is used.

According to the method of manufacturing a gold bar or a silver bar according to the present invention, an expensive rolling device is not used for manufacturing a gold bar or a silver bar. That is, the cost for equipping the manufacturing apparatus can be reduced. In addition, since a gold bar or a silver bar is manufactured through a continuous manufacturing process, it is possible to simplify the process and to miniaturize the workplace. In addition, it is easy to separate the production process and improve the product productivity. In addition, since characters and patterns can be displayed through engraving without using a template, there is no need to newly produce templates when characters or patterns are changed. Also, gold bars or silver bars have hardened surfaces, even if gold bars or silver bars are made of high purity gold or silver. Thus, it is possible to imprint sophisticated characters or patterns on the surface of a gold bar or silver bar. That is, it is easy to diversify the designs of gold bars or silver bars. In addition, the manufactured gold bar or silver bar has a surface that is not rough and has a high gloss, and various pictures are printed in color on these surfaces. Therefore, the color feeling of the gold bars or silver bars can be varied to improve the aesthetics, and product differentiation can be obtained. In addition, the gold bars or silver bars produced can be coated with a surface to prevent discoloration and scratches. That is, the storage life of the gold bars or silver bars can be improved.

1 is a schematic view showing a semi-finished product manufactured by a method of manufacturing a gold bar or a silver bar according to an embodiment of the present invention.
2 is a flowchart illustrating a method of manufacturing a gold bar or a silver bar according to an embodiment of the present invention.
3 is a flowchart showing a casting step of the first semi-finished product in Fig.
FIG. 4 is a flowchart showing a cleaning step of the first semi-finished product in FIG.
Fig. 5 is a flowchart showing a molding step to the second semi-finished product in Fig. 2. Fig.
6 is a flowchart showing the heat treatment step of the second semi-finished product in Fig.
Fig. 7 is a flowchart showing the buffing process steps of the second semi-finished product in Fig. 2. Fig.

Hereinafter, a method of manufacturing a gold bar or a silver bar according to the present invention will be described with reference to the accompanying drawings.

The embodiments disclosed herein relate to a method of making gold bars or silver bars using high purity gold or silver as a raw material. The object of the manufacturing method of the embodiment is not limited to a gold bar or a silver bar but also includes production of a bar-shaped product by using gold or silver alloy or other noble metal (e.g., platinum group element) as a raw material.

1 to 7, a method of manufacturing a gold bar or a silver bar according to an embodiment of the present invention (hereinafter referred to as a bar manufacturing method) (10 to 30) of various stages. In the embodiment, as the raw material 1, gold or silver having a purity of 99.99% or more, that is, pure gold or pure silver is used. The raw material 1 has a granule shape, but is not limited thereto.

In the embodiment, the raw material 1 is produced as a product 40 in the state in which the surface is imprinted and color-printed through three-stage semi-finished products. Among the semifinished products of the three stages, the first semi-finished product 10 is cast from the raw material 1 in order to make the raw material 1 of the granule into one lump. Of the three semi-finished products, the second semi-finished product 20 is formed from the first semi-finished product 10 by hardening the surface by work hardening and heat treatment. Of the semi-finished products of three stages, the third semi-finished product 30 is molded from the second semi-finished product 20 for engraving on the surface and for color printing. According to the above bar manufacturing method, the manufacturing process of making the third semi-finished product 30 from the raw material 1 is continuously performed. Therefore, it is easy to simplify the manufacturing process and to make the worksite small. In addition, the manufacturing process can be divided and the product productivity can be improved.

The workplace for performing the bar manufacturing method may include an inspection device, a casting device, a cleaning device, a molding device, a bar removal device, a heat treatment device, a stamping device, a printing device, and a packaging device. As the inspection apparatus, a length measuring apparatus and a mass measuring apparatus may be provided, and a surface roughness measuring apparatus and a gloss measuring apparatus may be further provided. The casting apparatus may include a crucible, a melting furnace, and a mold. Also, the cleaning device may include a cleaning container containing a cleaning liquid, and a wet tumbling device. As the molding apparatus, a mold and a press apparatus may be provided. The bar removing device may be provided with a grinder. The heat treatment apparatus may include an oxygen torch and a heating chamber. The engraving apparatus may be provided with an engraving press such as a meta machine. The printing apparatus may be a flat type color printer. The packaging device may be provided with a vacuum packaging machine. Such devices can be arranged in various ways in the workplace according to the manufacturing process sequence. In addition, some devices may be used in multiple stages of manufacturing.

Referring to FIG. 2, in the bar manufacturing method, the manufacturing processes of the first to third semi-finished products 10 to 30 are continuously performed. This bar manufacturing method involves casting a raw material into a first semi-finished product (S110) and washing the first semi-finished product (S120) with respect to the first semi-finished product (10). Then, in relation to the second semi-finished product 20, the cleaned first semi-finished product is molded into a second semi-finished product (S210), a burr is removed from the surface of the second semi-finished product (S220) A step S230 of cleaning the second semi-finished product, and a step S250 of buffing the second semi-finished product. In addition, regarding the third semi-finished product 30, a step S310 of molding the second semi-finished product into the third semi-finished product and a step S320 of stamping the third semi-finished product are included. In addition, the bar manufacturing method may further include color printing (S330) the third semi-finished product after the step S320 of stamping the third semi-finished product, and coating the surface of the third semi-finished product (S340) . In addition, the bar manufacturing method may further include a step S350 of coating the surface of the third semi-finished product (S340) and then packaging the third semi-finished product (S350).

First, in step S110 of casting the raw material into the first semi-finished product, the raw material 1 of the granule is cast into the first semi-finished product 10 having a rectangular parallelepiped shape. 3, the casting step S110 includes a step S111 of charging the raw material into the crucible, a step S112 of melting the raw material using the melting furnace, a step of injecting the molten raw material into the mold, A step S113 of casting the semi-finished product and a step S114 of inspecting the first semi-finished product.

The raw material 1 is charged into the crucible 2 (see Fig. 1) after its mass is measured through a mass-measuring device, for example, an electronic scale or the like. Thereafter, the crucible 2 is charged into the melting furnace, and heated so that the solid raw material 1 charged therein is dissolved. In the embodiment, a high-frequency melting furnace is used, but the present invention is not limited thereto. The high-frequency melting furnace can heat the crucible (2) to a temperature equal to or higher than the melting point of the raw material (1). The crucible (2) has a structure in which a plurality of cylinders are superposed. Concretely, the crucible 2 includes a carbon cylinder 2b, a ceramic cylinder 2a superimposed on the outside of the carbon cylinder 2b, and a boron nitride (BN) cylinder 2c superimposed on the inside of the carbon cylinder 2b I have. The carbon cylinder 2b generates heat in response to a high frequency generated in the high-frequency melting furnace. The ceramic cylinder 2a protects the carbon cylinder 2b from an impact or the like and keeps the carbon cylinder 2b at a low temperature, thereby reducing heat loss. The nitrided boron cylinder 2c prevents the powder produced by oxidation of the carbon cylinder 2b from flowing into the raw material 1. [ Since the carbon cylinders 2b are consumed by oxidation, it is confirmed that the crucible 2 has abnormality periodically.

When the raw material (1) is completely dissolved in the melting furnace, the molten raw material (1) is poured into a mold to cool it to be the first semi-finished product (10). Since the molten raw material (1) is at a high temperature of about 1000 캜, if it is injected directly into a cold mold, unexpectedly, a phenomenon may occur. Therefore, in the embodiment, the mold is heated to a predetermined temperature, for example, about 100 DEG C so as to prevent the loss of the raw material 1 and prevent a safety accident. Further, the mold is formed of a carbon material. Such a mold is excellent in thermal resistance and has a low coefficient of thermal expansion and is not easily deformed even at a high temperature. In addition, it has an inert property that does not chemically react with the raw material (1), and does not lower the purity of the raw material (1). In addition, since the thermal conductivity is excellent, the injected high-temperature raw material 1 can be rapidly cooled.

The first semi-finished product 10 is not cooled to room temperature in the mold, and is cooled to room temperature after being separated from the mold at a temperature of 650 to 750 캜, preferably about 700 캜. When the temperature of the first semi-finished product 10 is about 700 ° C, the surface of the first semi-finished product 10 is solidified to maintain a constant shape even if it is separated from the mold. The internal structure of the first semi-finished product 10 can be uniformly solidified by separating and holding the first semi-finished product 10 from the mold during cooling. When the first semi-finished product 10 in the mold is at a temperature exceeding 750 캜, the surface is not sufficiently solidified and is difficult to separate from the mold. When the temperature of the first semi-finished product 10 in the mold is lower than 550 占 폚, the degree of solidification from the surface contacting the mold and the degree of solidifying from the surface exposed to the air are different, It is difficult to coagulate so as to become uniform.

The first semi-finished product 10 separated from the mold and cooled to room temperature is checked for mass and size and subjected to an inspection step S114 to check whether bubbles are formed on the surface. The mass and size of the first semi-finished product 10 can be confirmed by using an inspection apparatus, and bubble marks can be visually confirmed. In the embodiment, the first semi-finished product 10 has a size of 108 mm in width, 58 mm in length and 15 mm in thickness.

The inspected first semi-finished product 10 is cleaned to remove impurities adhering to the surface (S120). The foreign matter may be powder generated from the heated crucible 2, dust in the workplace, or the like. 4, the cleaning step S120 includes a first cleaning step S121 for oxidizing and removing foreign matter from the surface of the first semi-finished product, a second cleaning step S122 for cleaning the first semi-finished product using a wet tumbling device, And a cleaning step S122. Further, it may further comprise an inspection step S123 of checking the mass of the first semi-finished product 10 after the second cleaning step S122. This inspection step S123 may be performed after the first cleaning step S121.

In the first cleaning step S121, the first semi-finished product 10 is immersed in the cleaning solution contained in the cleaning bath. An aqueous solution of hydrogen peroxide (H ₂ O ₂ ) is used as the washing solution. The aqueous hydrogen peroxide solution has a high oxidizing power and can remove foreign matter adhering to the surface of the first semi-finished product 10 by oxidation. In the first cleaning step S121, foreign matter can be physically removed. For example, the surface of the first semi-finished product 10 taken out from the cleaning liquid can be rubbed with a cleaning brush or the like to remove foreign matter.

The first semi-finished product 10 is rinsed again using a wet tumbling device after removing the water (washing solution). The first semi-finished product 10 is cleaned by the liquid flares injected into the wet tumbling device and a plurality of beads rotating therein, and the surface is smoothed and smoothed. The washed first semi-finished product 10 in the wet tumbling apparatus is inspected for mass confirmation after removal of water (light). As described above, by washing the first semi-finished product 10 in the first and second order, defective products can be prevented from being generated by foreign matter in the subsequent step.

The washed first semi-finished product 10 is molded into the second semi-finished product 20. [ Step S210 of molding the first semi-finished product into the second semi-finished product includes heating the surface of the first semi-finished product (S211), pressing the heated first semi-finished product to the second semi-finished product (S212) and cooling the pressurized second semi-finished product to room temperature (S213).

In order to heat the surface of the first semi-finished product 10, the first semi-finished product 10 is carried into the heating chamber and the surface is heated by the oxygen torch. When the washed first semi-finished product 10 is directly pressed without heating, the first semi-finished product 10 is in a state in which it is not softened. Therefore, a large pressing force is required at the time of molding into the second semi-finished product 20, so that a large-sized press apparatus must be used. In addition, the second semi-finished product 20 which is not heated before pressurization and has been molded has a high density and does not have a dense internal structure. Further, when there is a bubble mark on the surface of the first semi-finished product 10, it is difficult to remove it. Therefore, the first semi-finished product 10 is press-molded into the second semi-finished product 20 in a heated state so as to be in a loose state. In an embodiment, the first semi-finished product 10 is heated to a temperature in the range of 750 to 850 캜, preferably about 800 캜. During the heating of the first semi-finished product 10, the first semi-finished product 10 can be heated in the heating chamber while being contained in the mold. At this time, one side of the first semi-finished product 10 is heated by the oxygen torch and continues until the opposite side of the opposed first semi-finished product 10 becomes red. Heating by the oxygen torch continues until the first semi-finished product 10 becomes a red heat state. In order to uniformly heat the first semi-finished product 10, the first semi-finished product 10 may be heated upside down in the mold. The mold used for molding the second semi-finished product 20 is made of a steel material for die casting and is not easily deformed by heating. When the temperature for heating to soften the first semi-finished product 10 is less than 750 캜, it is difficult to heat one side of the first semi-finished product 10 so that the opposing side opposite to the first semi-finished product 10 becomes a glowing state. When the temperature for heating to soften the first semi-finished product 10 exceeds 850 캜, the first semi-finished product 10 becomes excessively soft and is difficult to press so as to become the second semi-finished product 20 .

After the first semi-finished product 10 is heated, the mold taken out of the heating chamber is carried into the press apparatus. Thereafter, the first semi-finished product 10 in the mold is pressed by the press apparatus so as to be the second semi-finished product 20. In the embodiment, the first semi-finished product 10 is pressed with a pressing force of 135 to 145 kgf / cm 2, preferably 140 kgf / cm 2. When the pressing force of the press apparatus is 135 kgf / , It is difficult to deform the first semi-finished product 10 into the second semi-finished product 20. If the pressing force exceeds 145 kgf / cm2, the degree of deformation is large and burrs are formed on the surface of the second semi-finished product 20 easy. In the embodiment, the press apparatus has a press head which is driven up and down, and the press head presses the upper surface of the first semi-finished product 10 so that the first semi-finished product 10 is moved in the thickness direction (the same direction as the drive direction of the press head) Lt; / RTI > Since the first semi-finished product 10 softened by heating has electrical conductivity, the lateral and longitudinal lengths (directions intersecting the driving direction of the press head) can be changed by the pressing force applied up and down.

The second semi-finished product 20 deformed from the first semi-finished product 10 by pressurization has a thickness smaller than that of the first semi-finished product 10 and has rounded corner portions. Further, the second semi-finished product 20 may have a strip-shaped recess 21 on its surface. After completion of the molding, the second semi-finished product 20 is separated from the mold and cooled to room temperature. At this time, the second semi-finished product 20 is soaked in the cooling water and quenched, thereby preventing the change occurring inside the second semi-finished product 20 during cooling. That is, the second semi-finished product 20 can keep the stable state at high temperature at room temperature.

On the surface of the second semi-finished product 20, a burr projected by pressing using a press apparatus may be formed. Therefore, the step of removing burrs from the surface of the second semi-finished product (S220) is performed. A grinder is used to remove burrs from the surface of the second semi-finished product 20. When the burr removal is completed, a test is performed to confirm that the mass of the second semi-finished product is not satisfied.

The deburred second semi-finished product 20 is subjected to a heat treatment step S230. The heat treatment step S230 includes a step S231 of heating the second semi-finished product to a predetermined temperature and a step S232 of quenching the heated second semi-finished product, as shown in Fig. In the embodiment, the second semi-finished product 20 is heated to about 550 to 650 占 폚, preferably about 600 占 폚. When the heat treatment temperature of the second semi-finished product 20 is less than 550 占 폚 or exceeds 650 占 폚, internal structure of the second semi-finished product 20 can not be changed or can not be prevented from being excessively changed. That is, it is difficult to harden the second semi-finished product 20 through the heat treatment.

Through heat treatment such as quenching after heating, the second semi-finished product has a dense and dense internal structure. In addition, the second semi-finished product 20 has a hardened surface. In the embodiment, the heat treatment step (S230) is performed once, but it may be repeated a plurality of times depending on the degree of hardening of the surface of the second semi-finished product (20).

The heat-treated second semi-finished product 20 may have foreign matter or unevenness on its surface while being subjected to the molding step S210, the deburring step S220 and the heat-treating step S230 which are performed before. Therefore, a cleaning step (S240) is performed to remove foreign matter or unevenness. To clean the second semi-finished product 20, a wet tumbling device, such as the second cleaning step of the first semi-finished product, is used. In the cleaning step S240, the remaining water (photocatalyst) remaining on the surface of the second semi-finished product 20 is removed. In addition, the cleaning step S240 may include an inspection step of confirming the weight of the second semi-finished product 20.

The washed second semi-finished product 20 is subjected to a buffing treatment step S250 so that the surface thereof can have a high gloss. 7, the buffing processing step S250 includes a step S251 of polishing the second semi-finished product using a buffing device, and a step S252 of washing the second semi-finished product using the steam washer do. If the second semi-finished product 20 is polished with a buffing device and then wiped with a dry cloth, scratch marks may be formed on the surface thereof. Thus, a cleaning is performed using a steam washer to remove the photocatalyst and the like from the surface of the second semi-finished product.

The second semi-finished product 20 which has been subjected to the buffing treatment is placed in a mold and is press-formed into a third semi-finished product 30 by a press apparatus. The pressing force applied by the pressing apparatus to press the third semi-finished product 30 may be the same as the pressing force applied when the first semi-finished product 10 is molded into the second semi-finished product 20. [ The pressing direction applied to the second semi-finished product 10 may be the same as the pressing direction applied when the first semi-finished product 10 is molded into the second semi-finished product 20. [ In the molding step S310 of the third semi-finished product, unlike in the molding of the second semi-finished product, heating is not performed. That is, the degree of deformation of the third semi-finished product 30 from the second semi-finished product 20 by the pressure is small and is not heated before pressing to maintain the hardened surface of the second semi-finished product 20. During molding into the third semi-finished product 30, the surface is lapped, and a mold plated with a chromium alloy (CrN) is used. By this mold, the third semi-finished product 30 is pressed so as to have a smooth, high-gloss surface. The third semi-finished product 30 is subjected to pressure treatment and heat treatment a plurality of times in the process of molding the first semi-finished product 10 cast from the raw material 1 into the second semi-finished product 20 and the third semi-finished product 30, And a high-density internal structure. In addition, the third semi-finished product 30 has a surface harder than the surface of the second semi-finished product 20. [

And inspecting the third semi-finished product 30 after the molding of the third semi-finished product 30. In this inspection step, the mass, size, shape and the like of the third semi-finished product 30 are confirmed, and it is confirmed whether there is a bubble mark or a scratch mark on the surface. Further, the surface roughness and gloss of the third semi-finished product 30 can be confirmed.

After the inspection, the surface of the third semi-finished product 30 is imprinted using an impression press. At least one of purity, mass, product number, product designation, manufacturer's name, and manufacturer's logo formed on the surface of the gold bar or silver bar is printed on the surface of the third semi-finished product (30) It is engraved with a pattern. In addition, pictures or text entered in the stamping presses can also be imprinted on the surface of the third semi-finished product 30. The stamping press comprises a process controller, a user interface, a storage unit, and the like. The process controller consists of a microprocessor (computer). The user interface includes an input device for inputting or scanning characters, patterns, pictures or letters to be engraved, and an output device for displaying the appearance of being printed on the surface of the imaginary third semi-finished product. The storage unit stores a control program of the stamping press, various data, a recipe necessary for driving, and the like. The storage unit includes a computer-readable storage medium.

Because the third semi-finished product 30 has a hardened surface, it is possible to imprint elaborate characters, patterns, pictures or text. Therefore, the selection range of characters, patterns, pictures and letters that can be imprinted on the surface of the third semi-finished product is widened. That is, it is easy to diversify the designs of gold bars or silver bars. In the embodiment, characters for displaying the purity 41, the mass 42, the product number 43, and the manufacturer 44 are formed on the surface of the imprinted product 40, and the manufacturer logo 45 (See Fig. 1).

The imprinted third semi-finished product 30 may optionally undergo a color printing step S330. At the color printing step (S330), at least one of characters, patterns, and figures is color-printed on the surface of the third semi-finished product (30). In the embodiment, a 'golden god' is printed on the surface of the product 40 in engraved and color printed state (see FIG. 1). Here, characters and patterns may include purity, mass, product number, product representation, manufacturer's name, and manufacturer's logo. That is, characters or patterns for displaying the purity, mass, etc. of a gold bar or silver bar can also be displayed through color printing. Since the third semi-finished product 30 has excellent surface roughness, the third semi-finished product 30 has little smearing of the printing liquid during color printing. In addition, since the third semi-finished product 30 has a high gloss, it can exhibit color even with the inherent color of the metal, and can exhibit various colors in combination with the color at the time of color printing. In other words, it can improve the sense of beauty of gold bars or silver bars, and can have distinctive product differentiation from other products.

When the engraving and color printing described above is completed, the surface of the third semi-finished product 30 is coated. In this surface coating treatment step S340, a coating agent is applied to the surface of the third semi-finished product 30 to a thin thickness. In the embodiment, a coating method is used for the coating treatment, but a spraying method, a dipping method, or the like may be used. By coating the surface of the third semi-finished product 30, the third semi-finished product 30 is prevented from being exposed to the atmosphere. Therefore, discoloration can be prevented, and scratches can be prevented from occurring in the third semi-finished product 30 itself.

The third semi-finished product 30 whose surface is coated is packed so that it can be traded or collected. In this wrapping step S350, a vacuum packaging machine is used to wrap the third semi-finished product 30 in a vinyl wrapping transparent wrapping paper. In the packaging step S350, the third semi-finished product 30 wrapped with a wrapping paper, that is, a gold bar or a silver bar, may be individually packed in a packaging box.

In the above-described embodiment, the first to third semi-finished products determined to be defective through inspection may be crushed or dissolved and reused as a raw material for casting the first semi-finished product.

As described above, according to the method of manufacturing a gold bar or silver bar according to the embodiment of the present invention, it is possible to engrave a precise character or pattern on the surface with a machine, and to make a hardened surface Can be manufactured.

In the embodiment of the present invention, a method of manufacturing gold or silver into a bar shape has been described as an example, but the present invention is not limited thereto. In other words, the present invention can be applied to manufacturing various forms of money, medals, plaques, memorial plaques, and artifacts.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It will be obvious to those of ordinary skill in the art.

1: raw material
2: Crucible
2a: ceramic trough
2b:
2c: boron nitride
10: First half product
20: second semi-finished product
30: Third Semifinished Product
40: Gold bars or silver bars

Claims (13)

Casting a first semi-finished product from a raw material of gold or silver,
Washing the first semi-finished product,
Pressing the first semi-finished product after the heating to form a second semi-finished product,
Removing burrs from the surface of the second semi-finished product,
Heat treating the second semi-finished product,
Washing the second semi-finished product,
A step of buffing the washed second semi-finished product,
Charging the second semifinished product, which has been subjected to the buffing treatment, into a metal mold, pressing the metal mold into a third semi-finished product,
Stamping the surface of the third semi-finished product
≪ / RTI > The method of claim 1, further comprising color printing the surface of the third semi-finished product after the imprinting step. 3. The method of claim 2, further comprising coating the surface of the third semi-finished product after the imprinting step or after the color printing step. 4. The method of claim 3, further comprising packaging the third semi-finished product after the coating process. The process for producing a gold or silver bar according to any one of claims 1 to 4, wherein the raw material of gold or silver has a purity of 99.99% or more. The method of claim 1, wherein the first semi-finished product in the casting step of the first semi-finished product is separated from the mold at a temperature range of 650 to 750 ° C and is maintained at room temperature. The method of manufacturing a gold bar or a silver bar according to claim 1, wherein in the casting step, the raw material is melted using a crucible in which a ceramic barrel, a carbon barrel and a nitrided boron bar are sequentially stacked. The method according to claim 1, wherein the washing of the first semi-finished product
A first cleaning step of oxidizing and removing foreign substances from the surface of the first semi-finished product,
And a second cleaning step of cleaning the surface of the first semi-finished product using a wet tumbling device. The method of manufacturing a gold bar or a silver bar according to claim 8, wherein the first semi-finished product is immersed in a washing solution in the first washing step, and the washing solution is an aqueous hydrogen peroxide solution. The method according to claim 1, wherein the forming of the second semi-finished product comprises:
Heating the surface of the first semi-finished product,
Pressing the heated first semi-finished product; and
And cooling the first semi-finished product to room temperature. The method of claim 1, wherein in the heat treatment step, the second semi-finished product is heated and quenched to 550 to 650 ° C. 2. The method of claim 1,
Polishing the washed second semi-finished product using a buffing device,
And washing the second semi-finished product using a steam washer. The method of manufacturing a gold bar or a silver bar according to claim 1, wherein a surface of the third semi-finished product is lapped and a chromium-plated mold is used.

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