JPS635182B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for producing germanium buttons and an apparatus for producing the same, mainly for eliminating and treating pain by acupressure effect and releasing into the air positive or negative charges accumulated in the affected area. It is.

In recent years, therapeutic tools and devices for the treatment of the human body and for maintaining and promoting health that apply the meridian secret holes of Oriental medicine have been on the market, and the germanium button of the present invention is one of them, and the germanium button of the present invention is one of them. Less than 1cm, several mm in height
It is a small product. When manufacturing such relatively small and thin products in large quantities,
Powder sintering is often used, in which molded bodies of metal powder are arranged on a sintering plate and sintered in a furnace.This method has also been used to manufacture germanium buttons, but this method requires no pressing. It was necessary to make delicate adjustments to the selection of the binder, the selection and arrangement of the sintering plates, and the sintering temperature.

In addition, there is a well-known casting method (hereinafter referred to as the molding method) in which a melt of metal or alloy is solidified in the holes of a mold that have holes that match the shape of the product.
However, because the germanium button is small, the molten metal becomes round due to surface tension and solidifies in that shape, making it impossible to obtain a product with a predetermined shape.

The present inventors solved the drawbacks of the above conventional method,
In order to provide a manufacturing method and manufacturing apparatus that are simple and suitable for mass production, we focused our studies on the molding method, which has a simple technical content, and as a result, we have arrived at the present invention. That is, the gist of the present invention is as follows: (1) When manufacturing a germanium button using metal germanium powder, a hole matching the shape of the germanium button is formed in a mold, and a metal is inserted into the hole. A method for producing a germanium button, which comprises filling germanium powder and inserting a push rod into the hole, melting the germanium powder by raising the temperature, and pressing the surface of the melt with the weight of the push rod. , (2) consisting of a female mold with a hole that matches the shape of the germanium button, and a male mold with a protrusion that is inserted into the hole of the female mold, and the female mold A device for producing germanium buttons, characterized in that the surface of the melt formed by melting germanium powder filled in the holes of the mold due to temperature rise is pressed by the weight of the male mold through the protrusions. , It is in.

Next, the present invention will be explained with reference to the drawings.

FIGS. 1 and 2 are shape diagrams of an example of a germanium button of the present invention, and FIG. 3 is a plan view and a sectional view of a mold for manufacturing a germanium button of the present invention.

In the present invention, a hole is formed in a female mold to match the shape of the germanium button of the present invention, and the hole is filled with metal germanium powder pulverized in a ball mill or stamp mill, and the metal is heated in an atmospheric furnace. The melting point of germanium is 935℃, preferably 950℃
The hole in the female mold is heated to a temperature range of 1100°C to 1100°C to prevent the surface of the melt from becoming rounded due to surface tension, and to give the upper end of the germanium button a predetermined shape. The germanium button can have a predetermined shape by inserting a male protrusion having a predetermined end face into the button and solidifying the melt in this state. It is not necessary to forcefully press the protrusion from above; it is sufficient to simply press the protrusion with the weight of the male mold. In this case, the amount of melt should be slightly larger than the volume of the space formed by the female mold and the male mold, and the excess melt should be poured into the hole drilled in the female mold and the protrusion of the male mold. so as to escape through the gap between the mold and the mold (hereinafter referred to as the mold gap). As a result, burrs are generated, but the gap between the molds should be such that the burrs can be easily removed by barrel polishing or the like.

1 for one mold made of graphite etc.
It is of course possible to make more than one hole,
By manufacturing the push rod accordingly, a large number of germanium buttons can be obtained. As a mold, graphite is preferred because of its excellent workability, but magnesia, alumina, silica, etc. can also be used. A mold is generally a combination of a female mold that has a product shape and a male mold that shapes the product shape.
Fill the female mold with metal germanium powder as it is, or apply a mold release agent such as ultra-high temperature mold release agent such as boron nitride, bone ash, calcium stearate, or zinc stearate, and then place the male mold on top of it. , the temperature is raised and melted, excess melt is released through the gap in the mold, and the product is then cooled and released from the mold.

By the way, in the molding method, it is common to provide a punching taper in the hole of the female mold for mold release and to apply a mold release agent, and as already mentioned, this is exactly the same in the case of the present invention. However, even if such measures are taken, it may be difficult to release the button body from the mold. In this case, an attempt is made to release the mold by, for example, slamming the mold with the hole facing down. As mentioned above, the mold is made of ceramics such as graphite, alumina, and magnesia, and is therefore easily damaged. Furthermore, when a mold release agent is used, there is a drawback that the surface of the product cannot be finished smoothly.

In order to overcome this drawback, the female mold is divided into two parts at the boundary between the body and the bottom of the germanium button.The female mold can be easily separated into upper and lower parts, so that the body can be separated from the bottom of the button. It became easy to release the mold by applying force to it. In particular, if the bottom of the germanium button is convex, force can be easily applied to the bottom after separating the female mold into upper and lower parts, so in this case it is not necessary to divide the female mold into two. This is extremely convenient for mold release.

The melting atmosphere in the present invention is hydrogen, helium,
A single reducing or inert gas such as nitrogen or argon or a mixture thereof is used.

Next, the present invention will be specifically explained using examples.

Example 1 The germanium powder at the bottom of the sieve, which was pulverized with a stamp mill and separated with a 60-mesh sieve, was used as a raw material. The mold is made of graphite and has a diameter of 7.4 as shown in Figure 1.
A female mold with perforations was used so that 20 disk-shaped products of mmφ×7.2mmφ×2.5mmh could be made. To manufacture germanium buttons, first, boron nitride is applied to the inner wall of the hole of the female mold, then 0.5 g of the germanium powder is filled into each hole of the female mold, and then the germanium powder is heated in an atmospheric furnace with nitrogen. 1050 with replacement
The temperature was raised to °C, held for 30 minutes, and then cooled. After removing the male mold having the same number of protrusions as the holes of the female mold, the female mold was tapped lightly with its holes facing down to release the solidified germanium button. At this time, it was somewhat difficult to release the germanium buttons from the mold, but by repeatedly tapping the female mold, all of them were successfully released. Also, due to the use of a mold release agent, the skin of the germanium buttons that were released from the mold was slightly rough, but by barrel polishing the buttons, the burrs were removed and the skin became clean.
A product with a good surface condition was obtained.

Example 2 Graphite of 55mm x 205mm x 15mm has an upper end a7.8mmφ, a lower end b7.3φ, and a depth as shown in Figure 3.
A truncated conical hole of c5mm and a depth further below the lower end b.
A pair of two-part female mold with 100 conical holes of d0.5 mm and a male mold with 100 cylindrical protrusions of 7 mm in diameter and 3 mm in height on graphite measuring 55 mm x 205 mm x 10 mm were used.

65% of metal germanium powder ground in a ball mill
The powder separated by the mesh sieve was used as the raw material, and this powder was placed on a female mold, cut with a rubber spatula, and placed evenly into each hole. The amount of germanium powder was 51 g in total. After tapping this powder, a male mold was placed on top of it, and it was placed in an atmospheric furnace, evacuated, and replaced with N ₂ gas. At this time, 5 to 10% of _H2 gas may be added. After raising the temperature to 1050℃ and holding it for 30 minutes, let it cool and take it out of the furnace, remove the female molds from each other, and insert the protruding conical part of the germanium button into the male mold with the hole of the female mold with the germanium button attached facing down. When I pushed it with the protrusion, I was able to easily remove all the pieces. Next, burrs were removed by barrel polishing to obtain a germanium button with a flat bottom end of 7.3 mmφ and a height to the top end of 2.5 mm with a clean surface texture.

For comparison, I was able to finally release all of the pieces using the same type of female mold, which was made in one piece, after several dozen hits.

[Brief explanation of the drawing]

Figures 1 and 2 are shape diagrams of examples of germanium buttons manufactured according to the present invention, Figure 3a,
b, c, and d are diagrams showing the shape of a mold for manufacturing a germanium button having the shape shown in FIG. 2; In the figure, A, a...The diameter of the upper end of the body;
B, b...Diameter of the lower end of the body part, C, c...Height of the body part, D, d...Height of the conical part, E...Female type plan view (body part), Es...Female type Cross-sectional view (body part), F... Female type top view (conical part), Fs... Female type cross-sectional view (conical part), G... Male type cross-sectional view.

Claims (1)

[Scope of Claims] 1. When manufacturing a germanium button using metal germanium powder, a tapered hole corresponding to the shape of the germanium button is formed in a mold, and the hole is filled with metal germanium powder. At the same time, a push rod is inserted into the hole, the germanium powder is melted by raising the temperature, and the surface of the melt is pressed by the weight of the push rod. 2 The shape of the germanium button consists of a female mold with matching tapered holes and a male mold with a protrusion that is inserted into the hole of the female mold. 1. An apparatus for manufacturing germanium buttons, characterized in that the surface of a melt formed by melting germanium powder filled in the mold due to temperature rise is pressed by the weight of the male mold via the protrusion. 3 Divide the female mold into two at the boundary between the tapered body and the bottom of the germanium button, and make a mold with a hole that matches the shape of the body and a hole that is flat or that matches the shape of the bottom. The mold consists of a two-part female mold, which is made up of a two-part female mold, and a male mold, which has a protrusion that is inserted into the hole in the body shape. 1. An apparatus for manufacturing germanium buttons, characterized in that the surface of a melt formed by melting due to heat is pressed down by the weight of the male mold through the projections.