KR101302724B1 - Restoration alloy for dental proshtetics - Google Patents

Abstract

It is a first object of the present invention to provide a restorative alloy for a dental prosthesis that has a similar physical value to that of the existing restoring alloy while reducing the content of expensive gold (Au).
In addition, the second object of the present invention is to add a relatively inexpensive silver (Ag) in order to reduce the content of gold, for the dental prosthesis made to be cheaper and easier to manufacture and use than conventional restoration alloys To provide a repair alloy.
In addition, the third object of the present invention is to prepare a repair alloy by adding zinc (Zn) to such a repair alloy, the zinc for the restoration of the dental prosthesis that acts as a deoxidizer during the casting of the repair alloy so that the repair alloy does not oxidize itself To provide a repair alloy.
Lastly, the fourth object of the present invention is that zinc (Zn), which has a low boiling point, is lost due to evaporation at the time of casting. In order to prevent this, it is possible to minimize evaporation by using a copper-zinc master alloy. To provide prosthetic repair alloys.

Description

Restorative alloy for dental prosthesis {RESTORATION ALLOY FOR DENTAL PROSHTETICS}

The present invention relates to a restorative alloy for dental prosthesis, and more particularly, to a restoring alloy having a similar physical property value as that of a conventional restoring alloy while reducing content of gold (Au), which is an expensive precious metal. .

Generally, when a part of the tooth is broken or damaged by caries, the dental prosthesis is repaired. The restoration treatment is performed by various methods such as a method of directly repairing with resin, an inlay and onlay for repairing a damaged tooth using an alloy, and a brass restoration covering a tooth in a crown shape.

Among these restorative treatments, alloys are used for inlays that cover part of the teeth, onlays that cover most of the teeth, and for brass restorations.

At this time, the alloy is used as a function of the damaged teeth, but do not feel the heterogeneity, etc. To achieve this purpose, the main components such as Au, Ag, Pt, Pd, Cu, In, and Zn The one produced at a predetermined ratio of is widely used.

In particular, these alloys must meet the following conditions because they must be applied to varying environments such as temperature, acidity and pressure changes in the oral cavity.

1) It must be able to withstand the chewing pressure that occurs when chewing food, so that the alloy does not wear out or deform.

2) Tooth, hardness and strength are similar, especially the color of teeth, so as not to feel heterogeneity between teeth and alloys.

3) There should be no corrosion or discoloration in the oral cavity and there should be no harm to human body.

As such, the most suitable element for various selection conditions is gold (Au). Gold has a relatively low melting point and excellent castability, and in particular, gold does not oxidize even in air. In the case of alloys used for inlays or onlays, Au-Ag-Cu alloys containing 80% or more of gold are frequently used.

However, these conventional repair alloys have the following problems.

1) Due to the high content of expensive gold, price competitiveness was lowered due to the increase in manufacturing and procedure costs. In particular, this problem is exacerbated when gold prices soar.

2) In order to solve this problem, there is a problem of developing an alloy with a low ratio of gold.

3) However, these low-rate alloys have similar properties compared to conventional alloys, but clinical trials have shown that the lower the content of gold, the more frequently the discoloration of the alloy surface (yellowing), fractures, cytotoxicity, And there are disadvantages such as having a hardness value stronger than the tooth hardness.

The first object of the present invention has been made in view of this point, and to provide a restorative alloy for dental prosthesis to reduce the content of expensive gold (Au) and to have similar physical properties as the existing repair alloy.

In addition, the second object of the present invention is to add a relatively inexpensive silver (Ag) in order to reduce the content of gold, for the dental prosthesis made to be cheaper and easier to manufacture and use than conventional restoration alloys To provide a repair alloy.

In addition, the third object of the present invention is to prepare a repair alloy by adding zinc (Zn) to such a repair alloy, the zinc for the restoration of the dental prosthesis that acts as a deoxidizer during the casting of the repair alloy so that the repair alloy does not oxidize itself To provide a repair alloy.

Lastly, the fourth object of the present invention is that zinc (Zn), which has a low boiling point, is lost due to evaporation at the time of casting. In order to prevent this, it is possible to minimize evaporation by using a copper-zinc master alloy. To provide prosthetic repair alloys.

Dental restoration restoration alloy according to the first embodiment of the present invention for achieving this object, gold (Au) 60.0-78.0% by weight, silver (Ag) 16.6-35.0% by weight, copper (Cu) 5.0-7.3 weight Characterized by including a%.

In addition, the dental restorative alloy according to the second embodiment of the present invention, gold (Au) 60.00-78.00% by weight, silver (Ag) 16.60-35.00% by weight, copper (Cu) 4.99-7.30% by weight, zinc ( Zn) 0.01-0.20% by weight.

In particular, the zinc is characterized in that the supply is made in the form of a copper-zinc (Cu-Zn) mother alloy.

Finally, the copper-zinc (Cu-Zn) mother alloy is a brass-based copper alloy, characterized in that the weight percent of the copper is made by adding the remaining content minus the amount contained in the mother alloy.

According to the restorative alloy for dental prosthesis of the present invention has the following effects.

1) The content of gold can be lowered from the existing 80% by weight or more to 78% by weight or less.

2) In particular, by adding silver to reduce the content of gold while supplementing hardness and strength, the overall manufacturing cost can be lowered with little change in the properties of the repair alloy.

3) By adding zinc, the zinc is first oxidized during casting of the repair alloy to prevent oxidation of the alloy itself, thereby improving the quality of the repair alloy.

4) The zinc contained in a small amount has a low boiling point during casting, so that it is possible to further increase the anti-oxidation effect by using it in the form of a mother alloy so that no loss occurs due to evaporation.

Figure 1 is an enlarged photograph for showing the state of discoloration after the discoloration test for the repair alloy according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

(Embodiment 1)

The repair alloy according to the first embodiment of the present invention comprises gold (Au) 60.0-78.0% by weight, silver (Ag) 16.6-35.0% by weight, copper (Cu) 5.0-7.3% by weight.

Gold (Au) is the main constituent of the restorative alloy, which increases corrosion, discoloration, resistance and ductility. If the content of gold is lower than 60.0%, the corrosion, discoloration and resistance are reduced. If the content is more than 78.0% by weight, the strength of the material is reduced.

Silver (Ag) improves color control, hardness, strength and ductility of the repair alloy. That is, the restoration alloy becomes red due to the copper content, and the addition of silver controls the red color of the alloy. However, if the silver content is too high, not only corrosion resistance but also color change occurs. Therefore, in the present invention, silver is added at a ratio of 16.6-35.0 wt% to ensure the color of the repair alloy and the required physical properties.

Copper (Cu) increases the hardness and strength of the restoring alloy and makes it red. Such copper can increase the hardness and strength depending on its content, but if it is added too much, it is not only cytotoxic but also lowers discoloration and corrosion resistance. Therefore, in the present invention, by containing 5.0-7.3% by weight of copper, it is possible to obtain hardness and strength while minimizing harmful components.

The repair alloy according to the first embodiment of the present invention having such a weight ratio is produced by casting. The manufacturing process is briefly described as follows.

First, 60.00-78.00 weight of gold, 16.60-35.00 weight of silver, and 5.00-7.30 weight of copper are charged to the vacuum furnace.

Then, the internal pressure of the vacuum in the vacuum 10 ³ - 10 The following standard was created to ^-4 torr, and dissolved by injecting this inert gas, such as argon, of 18 ~ 24 torr to.

Finally, the molten molten metal is injected into a mold or the like provided in the vacuum furnace, and then a repairing alloy is manufactured by rolling through a rolling mill.

(Second Embodiment)

The repair alloy according to the second embodiment of the present invention, gold (Au) 60.00-78.00% by weight, silver (Ag) 16.60-35.00% by weight, copper (Cu) 4.99-7.30% by weight, zinc (Zn) 0.01-0.20 It comprises by weight percent.

Here, in comparison with the first embodiment, the repair alloy of the second embodiment has the same manufacturing method, but is cast by further adding zinc (Zn) to the contained element. Therefore, only the reason for adding zinc and the method of adding the same will be described.

Zinc (Zn) is charged as a deoxidizer when the elements are charged to cast the repair alloy and dissolved for the repair alloy, where it is oxidized before other elements (especially copper) are oxidized to prevent oxidation of the repair alloy itself. It works. Such zinc may be directly charged and used in a vacuum furnace in such proportions, or a master alloy may be used as described later.

In a preferred embodiment of the present invention, such zinc has a low boiling point when dissolved in a vacuum furnace may cause loss due to evaporation and the like. Therefore, it is preferable to add zinc using a master alloy to minimize such losses.

In this case, as the master alloy, it is preferable to use the element used in the present invention as much as possible. For this purpose, in the second embodiment of the present invention, a master alloy containing copper (Cu) is used. That is, in the second embodiment, the necessary zinc content is supplied using the copper-zinc master alloy (Cu-Zn), and the insufficient copper is charged further.

That is, the amount of zinc required in the second embodiment is all added through the master alloy, and the shortage of copper supplied through the master alloy is charged into the vacuum furnace. The method of determining such loading amount is as follows.

First, determine the content of copper and zinc in the Cu-Zn master alloy. At this time, the content thereof is determined in advance according to the type of alloy because it is an amount contained in the production of the master alloy. For example, in the case of brass-based copper alloys, copper is 77-96% by weight and zinc is comprised of 1-12%. This formulation will vary depending on the alloy produced according to the intended use, for the sake of simplicity, assuming that copper: zinc is 8: 1 (ie, 8 g of copper and 1 g of zinc are combined).

Meanwhile, in a preferred embodiment of the repair alloy according to the second embodiment of the present invention, in order to know the additional content of zinc, it is assumed that the weight of copper and zinc of the repair alloy is 5.00% by weight of Cu and 0.20% by weight of Zn, respectively. , The ratio of copper and zinc is 25: 1 (for convenience of explanation, it is assumed that copper and zinc required in the repair alloy according to the second embodiment are 25g and 1g, respectively).

This is required when using the copper-zinc (Cu-Zn) master alloy blended in the ratio of 8: 1, but the required zinc (1g) is satisfied, but the copper content is only 8g, so it needs more by the difference. . That is, in the second embodiment of the present invention, since 25g is required, in addition to 8g supplied through the copper-zinc master alloy, (25g-8g) = 17g of copper, which is equal to the difference, is charged into the vacuum furnace to obtain a repair alloy. Will be manufactured.

(Example)

Physical properties of the repair alloys prepared according to the examples and embodiments of the repair alloys according to the first and second embodiments of the present invention are as follows.

First, in FIG. 1, type A shows the content ratio of the zinc-free repair alloy according to the first embodiment, and types B to E show the content ratio of the repair alloy according to the second embodiment.

Kinds

Au (% by weight)
Ag (% by weight)
Cu (% by weight)
Zn (% by weight)
A

60.0
35.0
5.0
-
B

65.0
29.3
5.5
0.2
C

70.0
23.8
6.0
0.2
D

76.0
16.6
7.3
0.1
E

78.0
16.6
5.3
0.1

Each of the repair alloys prepared in the same ratio as in Table 1 was tested for mechanical properties according to the ISO 22674 standard. Mechanical properties of the repair alloy of the present invention according to the test results are shown in Table 2 below.

A

B
C
D
E
Yield strength (Mpa)

100.1
102.7
109.8
112.8
145
Elongation (%)

26.2
28.3
25,6
24.9
32.9
Vickers Hardness (VHN)

98.5
106.1
102.2
00.2
88.6

As shown in the above [Table 2], the mechanical test was performed according to ISO 22674, and the mechanical properties (yield strength, 80-179Mpa, elongation, more than 18%) required for dental prosthesis, especially inlay alloy, were satisfied. It can be used for dental prostheses.

<Discoloration test>

The color change test of the repair alloy according to the present invention was carried out as follows.

1) Test equipment: Tarnish tester (Myung sung industry, Korea)

2) Specimen: Diameter (10 ± 1) mm, Thickness (0.5 ± 0.1) mm

3) Test Procedure:

3-1) After polishing the specimen with silicon carbide abrasive paper, clean it.

3-2) Dip the specimen into aqueous sodium sulfide solution for 10-15 seconds per minute with a discoloration tester.

3-3) Clean the specimen after 72 hours

As described above, the specimens which finished the discoloration test were observed by visual comparison with the specimens which did not undergo the discoloration test. As a result, it was confirmed that there is no color difference between the test group subjected to the discoloration test and the control group not to the discoloration test. Figure 1 is an enlarged photograph to show the surface state of the specimen of the test group subjected to this discoloration test.

As described above, the repair alloy according to the present invention can not only reduce the content of expensive gold, but also improve the castability while having similar mechanical properties using the mother alloy.

Claims (4)

60.0-78.0 wt% of gold (Au), 16.6-35.0 wt% of silver (Ag), 5.0-7.3 wt% of copper (Cu).
60.00-78.00 wt% gold (Au), 16.60-35.00 wt% silver (Ag), 4.99-7.30 wt% copper (Cu), 0.01-0.20 wt% zinc (Zn) for dental prosthesis Restoration alloy.
3. The method of claim 2,
The zinc is made by supplying a copper-zinc (Cu-Zn) mother alloy, and the weight% of copper is added by subtracting the amount contained in the mother alloy to restore the dental prosthesis. .
The method of claim 3, wherein
The copper-zinc (Cu-Zn) mother alloy is a brass-based copper alloy,
The weight percent of the copper is a restorative alloy for dental prosthesis, characterized in that the addition of the remaining content minus the amount contained in the parent alloy.

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