JP2005336591A - Method for producing parent mixed metal for accessory - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for stably producing a parent mixed metal for an accessory, which has an effect of emitting far-infrared rays and can be variously formed into the accessory. <P>SOLUTION: The method for producing the parent mixed metal containing ceramic for the healthy accessory comprises: a ceramic-powder-charging step of charging 0.2 to 0.25 (wt.%) ceramic powder mainly made of silicon oxide with respect to the base metal, into the bottom of a crucible; a base-metal-charging step of charging the base metal of a noble metal onto the ceramic powder inside the crucible; a heating and melting step of heating the crucible having the ceramic powder and the base metal charged therein, to a melting temperature of the base metal in a high-frequency furnace to produce a molten material; a molding step of casting the molten material into a mold having a lower temperature than the heating temperature and leaving it; and a cooling step of naturally cooling a molded article taken out from the mold and then quenching it. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for manufacturing a mixed ingot for jewelry that exhibits a far-infrared effect.

Conventionally, it has been confirmed that the blood circulation of the body is improved by far infrared rays emitted from ceramics and the like. Thus, it is conceivable to use a ceramic piece or the like that emits far-infrared rays attached to the skin with a tape, but sticking for a long time is not preferable because it places a burden on the skin such as a rash. That said, it's cumbersome to change frequently to change the location.
On the other hand, in order to always wear a substance that emits far-infrared rays, it is conceivable to make a jewelry with ceramics.
There is no particular patent search for this issue.

However, since ceramic is not plastically deformed, it cannot be freely processed like a precious metal, so it is not suitable for use as a jewelry.
Therefore, a mixed ingot that is a mixture of both precious metal and ceramic can be considered, but it is difficult to mix a precious metal that melts at a high temperature and a ceramic that does not melt.
An object of the present invention is to provide a manufacturing method for stably manufacturing a mixed ingot for jewelry that has a far-infrared effect and can be variously processed as a jewelry.

  1st invention is a manufacturing method of the mixed ingot for health accessories containing ceramic, Comprising: The ceramic powder which has silicon oxide as a main component in a crucible bottom part is 0.2-0.25 ( The ceramic powder charging step to be charged), the bullion charging step for charging the precious metal bullion on the ceramic powder in the crucible, and the crucible into which the ceramic powder and bullion are charged are placed in the above-mentioned ground in the high frequency furnace. A heating and melting process that generates a melt by heating to the melting temperature of gold, a molding process in which the melt is poured into a mold having a temperature lower than the heating temperature, and a molded product taken out from the mold is naturally cooled and then rapidly cooled. And a cooling step.

The second invention is based on the first invention and is characterized in that the particle size of the ceramic powder is 0.5 (μm) to 1.0 (μm).
3rd invention presupposes the said 1st or 2nd invention, and repeats a metal | bulb metal injection | throwing-in process and a superheat melting process in multiple times, and is characterized in the point that a required amount of metal | metal | money is dividedly input in each metal | gold metal injection process. Have.
In other words, the total amount of bullion input in the local gold input process is the required amount of bullion.
The fourth invention is premised on the first to third inventions, and is characterized in that borax is put together with the ceramic powder into the crucible in the ceramic powder feeding step.

The fifth invention is based on the first to fourth inventions, and is characterized in that the metal is platinum and the temperature in the electric furnace in the heating and melting step is controlled to about 1700 ° C.
6th invention presupposes the said 1st-4th invention, and while the metal is gold | metal | money, the temperature in the electric furnace in the said heat-melting process is controlled at about 1000 to 1050 degreeC, It is characterized by the above-mentioned. Have
7th invention presupposes the said 1st-4th invention, and while the ingot is silver, the temperature in the electric furnace in the said heat-melting process is controlled to about 900 to 950 degreeC, It is characterized by the above-mentioned. Have

According to the 1st-7th invention, the mixed ingot for jewelry containing the component which exhibits a far-infrared effect can be manufactured stably.
According to the second aspect of the invention, it is possible to prevent the ceramic powder having a small specific gravity from being scattered and to manufacture a mixed metal in which the ceramic powder is uniformly dispersed in the metal.
According to the third invention, the dispersed state of the ceramic powder in the metal can be made more uniform.

According to the fourth invention, impurities can be removed, and a high purity mixed metal can be produced.
According to the fifth aspect of the invention, it is possible to manufacture a mixed ingot suitable for health accessories using platinum as the ingot.
According to the sixth aspect of the invention, it is possible to manufacture a mixed bullion suitable for health accessories using gold as a bullion.
According to the seventh invention, a mixed bullion suitable for health accessories can be manufactured using silver as a bullion.

  The method of manufacturing a mixed ingot for jewelry of the present invention includes a ceramic powder charging step of charging ceramic powder into a crucible, a metal charging step of charging a precious metal ingot on the ceramic powder, ceramic powder and precious metal, A heating and melting step in which a crucible charged with is heated in a high-frequency furnace to generate a melt, a molding step in which the melt is poured into a mold and allowed to stand, and a cooling step in which the molded product taken out from the mold is cooled. Become.

Below, one Embodiment of the said manufacturing method is described.
In the ceramic powder charging step, ceramic powder containing silicon oxide as a main component is charged at the bottom of the crucible. This ceramic powder is obtained by pulverizing ceramic containing silica, magnesium, sodium, calcium, etc. It is adjusted to 0.5 (μm) to 1.0 (μm). And the input amount of the said ceramic powder shall be 0.2-0.25 (weight%) with respect to a base metal.
Here, 1 (kg) of gold as a bullion and 2 (g) ceramic powder which is 0.2 (wt%) with respect to the bullion are used. That is, in the ceramic powder charging step, ceramic powder 2 (g) is charged to the bottom of the crucible.

Next, in the ingot charging step, 1 (kg) of gold particles as the ingot is put on the ceramic powder in the crucible to cover the ceramic powder. Ceramic powder has a smaller specific gravity than gold particles and is very fine so that it is easily scattered. However, the ceramic powder can be prevented from scattering by being covered with gold particles.
And the said crucible is installed in a high frequency furnace. The high frequency furnace is controlled within a range of about 1000 ° C. to 1050 ° C., which is the melting temperature of gold, and gold is melted.
When gold is melted into a fluid in the high-frequency furnace, the ceramic powder charged in the bottom of the crucible moves in the gold melt as the fluid flows.

  When the gold is melted, in the molding process, the melt in the crucible is poured into a mold having a temperature lower than the melting temperature, molded, and left to solidify. When the melt is solidified in the mold, the solid is taken out of the mold, transferred to a cooling process, naturally cooled, and then rapidly cooled using cooling water or cold air.

In the gold fluid sufficiently melted in the heating and melting step as described above, the ceramic powder flows and reaches the whole or is uniformly dispersed. If it is poured into a mold that is sufficiently lower than the melting temperature, the temperature of gold drops rapidly and the viscosity rises, which hinders the movement of the ceramic powder. In addition, the crystallization of gold is promoted by a rapid temperature decrease, and the ceramic powder is uniformly dispersed inside.
By removing it from the mold and further cooling, the state in which the ceramic powder is uniformly dispersed is fixed.

The solid material obtained as described above is a mixed ingot for jewelry.
As described above, the jewelry ingot for jewelry is a gold ingot in which ceramic powder is uniformly dispersed.
The ceramic powder dispersed in the gold bullion is a fine powder having a particle size of 1 (μm) or less and the content is 0.2 (% by weight). Yes. Therefore, the presence of the ceramic powder does not interfere with the plastic deformation of gold. Therefore, when forming a jewelry using this mixed metal, it can be freely processed by the same method as when using a metal.

On top of that, the far-infrared effect is achieved thanks to the ceramic powder dispersed inside.
Therefore, the accessory using the above-mentioned mixed bullion promotes blood circulation of the wearer, promotes metabolism, and as a result, removes waste products in the body and helps to recover muscle fatigue.
The ceramic powder also has the effect of absorbing electromagnetic waves and suppressing the influence of electromagnetic waves on the human body.
That is, according to the manufacturing method of the mixed ingot for jewelry according to the present invention, it is possible to manufacture an optimal mixed ingot as a material for health accessories.

In the above embodiment, the ceramic powder used as a raw material is adjusted to 0.5 (μm) to 1.0 (μm), but when the particle size of the powder exceeds 1 (μm) and is too large, If it contains a lot of ultra fine powder of 0.5 (μm) or less, the ceramic powder may be scattered during the ceramic powder charging process or the metal charging process. It becomes easy. In addition, the ultra fine powders easily aggregate with each other, and there is a problem that they cannot be uniformly dispersed in the metal. If the ceramic powder could not be uniformly dispersed, the properties of the mixed ingots would partially vary, making it difficult to process, and for the health benefits of jewelry made using this, Differences may occur depending on the product.
Therefore, it is necessary to adjust the particle size of the ceramic powder in the range of 0.5 (μm) to 1.0 (μm).

Furthermore, in the above embodiment, the entire amount of gold particles as a bullion is charged into the crucible at a time in the bullion charging process, but the bullion charging process and the heating and melting process are alternately repeated a plurality of times. An amount of gold may be divided and input.
For example, when 1 (kg) of gold is required, 200 (g) of gold is put on 2 (g) of ceramic powder, and in a heating and melting process, the gold is placed in a high-frequency furnace at 1000 ° C. to 1050 ° C. Is heated and melted, and then 300 (g) of gold is added and heated and melted, and further 500 (g) of gold is charged and heated and melted.

In this way, by gradually increasing the amount of the base metal, it is possible to make the dispersion of the ceramic powder in the base metal more uniform. This is because the ceramic powder is more easily dispersed uniformly in the metal when the content of the ceramic powder relative to the molten metal is higher.
That is, in the first heating and melting step, the ceramic powder can be uniformly dispersed by dispersing the ceramic powder in a half amount of the base metal, rather than introducing the entire amount of gold at once. Therefore, in the second heating and melting step, the mixed metal in which the ceramic powder is uniformly dispersed and the newly added metal are mixed, and the ceramic powder can be uniformly dispersed throughout. Furthermore, in the third heating and melting step, the mixed metal in which the ceramic powder is uniformly dispersed in the second heating and melting step and the newly added metal are mixed to uniformly distribute the ceramic powder throughout. Can be made.

In the above embodiment, an example is described in which gold is used as the bullion. However, even if other noble metals such as platinum and silver are used as the bullion, they are mixed by the same process as in the case of the gold. You can make bullion.
However, since it is necessary to heat the inside of the high frequency furnace in the heating and melting step to the melting temperature of the metal, it is necessary to adjust the temperature depending on the type of the metal used.
The temperature in the heating and melting step needs to be equal to or higher than the melting temperature of the metal, but more than necessary in order to quickly crystallize the metal when the melt is poured into the mold. It is not preferable to heat it.
Moreover, in the said ceramic powder injection | throwing-in process, if borax is thrown in with a ceramic powder simultaneously, the impurity contained in the raw material in a heating-melting process can be removed. Accordingly, it is possible to produce a mixed metal having a high purity with less impurities.

Claims (7)

  A ceramic powder manufacturing method for mixed ingots for jewelry containing ceramics, in which ceramic powder containing silicon oxide as a main component is added to the bottom of a crucible in an amount of 0.2 to 0.25 (% by weight) with respect to the base metal. A charging step, a bullion charging step of charging a precious metal bullion onto the ceramic powder in the crucible, and a crucible charged with the ceramic powder and bullion is heated to a melting temperature of the bullion in a high frequency furnace. Heating and melting step for producing a melt, a molding step for pouring the melt into a mold having a temperature lower than the heating temperature, and a cooling step for cooling the molded product taken out from the mold after natural cooling. A method for producing a mixed ingot for jewelry.   2. The method for producing a mixed ingot for jewelry according to claim 1, wherein the ceramic powder has a particle size of 0.5 (μm) to 1.0 (μm).   3. The method for producing a mixed ingot for jewelry according to claim 1 or 2, wherein the ingot injecting step and the heating and melting step are repeated a plurality of times, and a necessary amount of ingot is separately introduced in the local ingot introducing step. .   The method for producing a mixed ingot for jewelry according to any one of claims 1 to 3, wherein in the ceramic powder charging step, borax is charged into the crucible together with the ceramic powder.   The ingot for mixed jewelry according to any one of claims 1 to 4, wherein the ingot is platinum and the temperature in the electric furnace in the heating and melting step is controlled to about 1700 ° C. Method.   The ground metal is gold, and the temperature in the electric furnace in the heating and melting step is controlled to about 1000 ° C to 1050 ° C. The mixed ground for jewelry according to any one of claims 1 to 4, Gold manufacturing method.   The ground metal is silver, and the temperature in the electric furnace in the heating and melting step is controlled to about 900 ° C to 950 ° C. The mixed ground for jewelry according to any one of claims 1 to 4, Gold manufacturing method.