KR20120130882A - Ti-reinforced Zirconia abutment using brazing - Google Patents

Abstract

PURPOSE: A metal reinforced zirconia abutment is provided to reduce the fracture of the abutment by maintaining the strength of the abutment. CONSTITUTION: A metal reinforced zirconia abutment comprises a metal reinforced zirconia abutment by brazing bonding(128), an abutment which is made of zirconia or zirconia alloy, and a metal reinforcing member which is made of titanium alloy or other biocompatible alloy. The metal reinforcing member is combined with the abutment by brazing. The metal reinforcing member and the inner surface of the abutment are combined by a filler material. The metal reinforcing member is formed in the shape of a cap.

Description

Metal-reinforced zirconia abutment by brazing bonding {Ti-reinforced Zirconia abutment using brazing}

The present invention relates to a metal-reinforced zirconia abutment such as titanium by brazing bonding, and more particularly, to an abutment in which a metal reinforcing member is bonded to an inner surface of a zirconia abutment using a brazing method.

Dental implants (or implants) refers to joining an artificial tooth to a fixture after fastening a fixture corresponding to the root to the alveolar bone to a portion where the tooth is partially or totally lost in the oral cavity so as to adhere to the bone. Such an implant consists of a fixture corresponding to the root, and an abutment combining the artificial tooth and the fixture.

In this way, the abutment connects the fixture and the artificial tooth, and may protrude upward with respect to the gum and be exposed to the outside. Generally, abutments are made of titanium or titanium alloy, which is the same material as the fixture. Titanium has been widely used in the field of dental implants because of its good fusion with living organisms, no side effects, strong strength and poor deformation. However, because titanium has a dark gray color, the gum is thin, so it is aesthetically unfavorable when black is transmitted or exposed to the outside of the gum. In particular, when the all ceramic crown is attached on the titanium abutment, the metallic color is reflected and tooth color is not harmonized.

In order to solve the above problems of titanium abutments, abutments made of zirconia or zirconia alloys have been used. Zirconia also has good reactivity with a living body and particularly has a white color, so that even when exposed to the outside, zirconia does not significantly affect aesthetics. However, zirconia has a disadvantage in that breakage occurs easily when an impact is applied due to its large hardness. In particular, very large loads are repeatedly applied between the fixture and the coupling portion of the zirconia abutment. Such loads tend to break the conventional zirconia abutments easily.

In particular, the zirconia abutment is the biggest disadvantage is that the fixture and the connecting portion is formed so thin that it can be easily broken under load. In order to compensate for the fracture of the dental zirconia abutment, the portion connected to the fixture is made of titanium, and the upper titanium is attached to the zirconia abutment by adhesive cement. However, cement-bonded zirconia abutments are mechanically bonded rather than chemically bonded, resulting in the weakening of thinner portions of zirconia attached to titanium rather than strengthening zirconia abutments.

Accordingly, the present invention is derived to solve the above problems, by chemically bonding titanium or other metal reinforcing member to the inner surface of the zirconia abutment, to maintain a certain strength to minimize the fracture, while at the same time appearance It is intended to provide excellent metal reinforced zirconia abutments.

Metal-reinforced zirconia abutment according to an aspect of the present invention, the abutment formed by zirconia or zirconia alloy, is bonded to the inner surface of the abutment and in contact with the fixture, by a titanium alloy or other bio-friendly alloy It includes a metal reinforcing member is formed. And the metal reinforcing member is coupled to the abutment by brazing (brazing).

The titanium reinforced zirconia abutment according to the present invention may include one or more of the following embodiments. For example, the inner surface of the metal reinforcement member and the abutment may be coupled to each other by molten filler metal. And the filler metal may include silver (Ag), zirconia (Zr), titanium (Ti), nickel (Ni) and copper (Cu). In addition, the filler metal is characterized by having a melting point of 950 ℃ or less.

The metal reinforcing member may be in the shape of a frictional cap that is frictionally coupled to the frictional post that is connected to the fixture. The metal reinforcing member may be titanium, titanium alloy, gold or Cr-Co-Mo alloy, and the metal reinforcing member may be biocompatible metal.

Porcelain may be coupled to the upper portion of the zirconia abutment, and the metal reinforcing member may be connected to correspond to the upper structure of the fixture.

The filler metal may be provided between zirconia and the metal in powder form or in the form of a thin foil like foil.

Roughness of the reduction of the adhesive portion may be variously formed according to the surface size and shape of the adhesive force.

Metal reinforcement of the metal-reinforced zirconia abutment according to the present invention may be used in addition to titanium, other base metals such as gold alloy or CCM (Cr-Co-Mo). Gold alloy or CCM is not only excellent in biocompatibility but also resistant to mechanical load and resistant to fracture compared to zirconia and is widely used as a dental prosthetic material. Brazing filler metals, in which each metal and zirconia are effectively combined, can be used to fabricate strong metal reinforced zirconia abutments. Hereinafter referred to as 'titanium-reinforced zirconia abutment'.

The present invention mechanically or chemically couples the titanium reinforcing member to the inner surface of the zirconia abutment, thereby maintaining the strength to withstand external loads in spite of the small adhesive surface area and at the same time, when the filler metal is white in color, the titanium is excellent in appearance. Reinforced zirconia abutments can be provided.

1 is a cross-sectional view of a titanium reinforced zirconia abutment by brazing bonding according to an embodiment of the present invention.
2 is a cross-sectional view of the titanium reinforced zirconia abutment by brazing bonding according to another embodiment of the present invention.
3 is a cross-sectional view of the titanium reinforced zirconia abutment by brazing bonding according to another embodiment of the present invention.
4 is a cross-sectional view of a titanium reinforced zirconia abutment by brazing junction in accordance with another embodiment of the present invention.
5 is a cross-sectional view of a titanium reinforced zirconia abutment by brazing junction in accordance with another embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout the specification and claims. The description will be omitted.

1 is a cross-sectional view of a titanium reinforced zirconia abutment 100 by brazing bonding according to an embodiment of the present invention, and shows a state in which the fixture 180 is fastened.

1, the titanium reinforced zirconia abutment 100 by brazing bonding according to the present embodiment is to connect the crown 185 corresponding to the artificial tooth to the fixture 180, the fixture 180 The friction-maintaining metal post 120 fastened to the part and the friction-maintaining titanium reinforcing member 140 held by the frictional force on the upper part of the metal post 120 is maintained on the metal post 120 by the frictional force and the titanium The zirconia abutment 128 or zirconia porcelain crown 185 is coupled to the titanium reinforcing member 140 by brazing on the reinforcing member 140.

The zirconia abutment 128 may be directly coupled to the metal post 120 without friction with the titanium reinforcing member 140, but in this case, it is difficult to precisely control the amount of shrinkage during sintering of zirconia and also the friction of the sintered zirconia It is difficult to precisely process the inner surface of the surface, and there is a disadvantage in that zirconia may be fractured by the expansion pressure when the metal post 120 is frictionally inserted.

Friction-retaining metal cap form is easy to maintain friction and easy to process, so first make a metal cap, and zirconia abutment can be processed to allow the inner surface to be relaxed and bonded by metal cap and cement or brazing. I can make a butt. In this embodiment, the titanium cap and the zirconia abutment are joined by brazing to provide a fracture-resistant titanium reinforced zirconia abutment that is strong in fracture and effective in maintaining friction.

The metal post 120 includes a fastening part 160 screwed to a fastening hole formed in the fixture 180. The remaining portion of the metal post 120 protrudes out of the fixture 180.

The titanium reinforcing member 140 is coupled to the upper portion of the metal post 120. The titanium reinforcing member 140 is coupled to the metal post 120 protruding to the outside by a frictional force, and completely covers the metal post 120 protruding to the outside. If the titanium reinforcing member 140 is too thick, the thickness of the zirconia abutment becomes thin, so that the thickness to withstand the load. And the outer shape of the titanium reinforcing member 140 may be designed to have a sufficient bonding strength with the zirconia. The inner surface of the zirconia abutment has a shape corresponding to the outer surface of the titanium cap, but is formed such that a space exists so that friction force does not occur when the two are combined. A gap between the inner surface of the zirconia and the outer surface of the titanium cap may be provided about 10 to 500 μm. The filler metal is interposed between the spaces and may be provided in powder form or in foil paper such as foil.

Titanium reinforcement member 140 is coupled to the inner surface 124 of the zirconia abutment 128 is not exposed to the outside. In addition, when the filler metal has a silvery white color, it may cover the metal color of the titanium reinforcing member 140. Therefore, since the color of the titanium reinforcing member 140 which is generally gray is not exposed to the outside, the abutment 100 according to the present embodiment has an aesthetically superior advantage. At the connection with the fixture, a titanium surface of 0.5 ~ 2mm is exposed to this outside, which can be provided in various ways such as gold or pink by anodizing titanium, so that it can be in harmony with the gum color.

And the titanium reinforcing member 140 is interposed between the zirconia abutment 128 made of zirconia or zirconia alloy and the fixture 180 made of titanium or titanium alloy, thereby increasing the strength of the zirconia abutment 128. Reinforcement and not broken easily.

The zirconia abutment 128 is covered on the titanium reinforcing member 140, the porcelain crown 185 corresponding to the artificial tooth is coupled to the upper portion of the zirconia abutment 128. The zirconia abutment 128 is made of zirconia or zirconia alloy and thus has a white or tooth-like color. Porcelain is a type of ceramic for dental use. It is permeable and its color is strongly influenced by the color of the internal materials it contacts. Thus, porcelain on zirconia has a natural tooth tone and has an aesthetic advantage.

The zirconia abutment 128 may be made of zirconia (ZrO ₂ ), stabilized zirconia (SZ), partially stabilized zirconia (PSZ), or the like belonging to the oxide-based zirconia. Zirconia has excellent heat resistance, but at 1100 ° C and 2370 ° C, phase transformation of the crystal structure occurs, resulting in large volume change. Therefore, stabilized zirconia (SZ) in which MgO, CaO and Y ₂ O ₃ is dissolved in zirconia is used as the heat resistant material. In addition, partially stabilized zirconia (PSZ) or zirconia polycrystalline (TZP) may also be used to increase strength and toughness. Partially stabilized zirconia (PSZ) or zirconia polycrystals (TZP) are used as biomaterials such as artificial teeth and artificial skulls because ceramics are high strength and high toughness materials.

The inner surface of the zirconia abutment 128 and the outer surface of the titanium reinforcing member 140 are coupled to each other by the brazing filler metal space 130 formed through the filler metal by a brazing method. Brazing is a method of melting and bonding a filler metal below a melting point of both base materials to be joined at a temperature of about 450 ° C. or higher, and is widely used because the base metal does not go bad and can be joined between dissimilar metals. In brazing, a filler metal having a liquidus temperature of 450 ° C. or higher is melted to bond two base materials. The filler material is melted by the applied heat and flows between the two base materials by capillary action.

In the titanium reinforced zirconia abutment 100 by brazing bonding according to this embodiment, since the melting point of the titanium reinforcing member 140 is about 870 ° C. or more, the melting point of the filler metal should be low. In addition, the filler metal may have various materials, for example, 50% of silver (Ag), 20% of zirconia (Zr), 20% of titanium (Ti), and 5% of copper (Cu).

Silver (Ag) is the most useful and important element among brazing alloys, and has excellent corrosion resistance, electrical conductivity, and thermal conductivity. Silver is not strong on its own but has a strong strength when combined with other elements. In addition, since the silver alloy has a strong penetration force when molten, a strong bonding surface can be obtained. And since silver has a white color (white color), there is an effect of masking the black color of titanium, there is also an advantage in aesthetic appearance.

Copper (Cu) has as many characteristics as silver in brazing alloys. Although it has many advantages such as ductility, thermal conductivity, conductivity, corrosion resistance, and strong penetration, it is relatively inexpensive compared to silver. Therefore, in many places it is used as a substitute for silver. Also, unlike silver, copper is compatible with iron, nickel, and many refractory alloys. When copper and silver are combined at a ratio of 28:72, eutectic alloys of 780 ° C are formed to have a superior penetration ability with stronger ductility than copper or silver.

The brazing process can be variously classified according to the heating method. Torch brazing brazing with a torch, furnace brazing brazing in a furnace, induction brazing with induction heating as a heat source, brazing in a heated solution Dip brazing, resistance brazing using heat of resistance, and the like.

Such brazing is useful for joining dissimilar metals and has a stronger bond strength than other bonds. And brazing has the advantage of enabling sophisticated bonding.

Until now, it has not been possible to find a method of chemically and strongly bonding zirconia and other metals in the dental field. However, only zirconia can be used as an abutment so weak that fracture occurs easily. Although zirconia is aesthetically pleasing, it is not well used because of the risk of fracture. The conventional technique of combining zirconia and other metals has been to join by cement. However, the method has a disadvantage in that the binding force is weak, causing rupture of zirconia at the binding site. The present invention is expected to bring the effect of generalizing the use of zirconia abutments in implants beyond the limitations of the prior art by a breakthrough method in which a brazing method for bonding dissimilar metals or dissimilar materials is applied to an implant region.

2 is a cross-sectional view of a titanium reinforced zirconia abutment 200 by brazing bonding in accordance with another embodiment of the present invention.

2, the titanium reinforced zirconia abutment 200 by brazing bonding according to the present embodiment is coupled to the upper portion of the fixture 280 is exposed to the outside, the inner surface 224 of the titanium reinforcing member ( 240 is joined by brazing joint surface 230. In addition, a screw hole 260 is formed through the center of the abutment 200.

The abutment 200 according to the present embodiment is coupled to an upper portion of an external fixture and exposed to the outside. Since the titanium reinforcing member 240 is interposed between the zirconia abutment 200 and the fixture 280, the abutment 200 formed by the zirconia or zirconia alloy and the titanium or titanium alloy are formed. Fixtures 280 are not in contact with each other. Since the abutment portion 200 and the fixture 280 to which a large load is applied are interposed with a reinforcing member 240 made of titanium or titanium alloy, which is relatively excellent in strength, the abutment 200 It is possible to prevent the abutment 200 from being damaged by the load applied thereto.

The titanium reinforcing member 240 has a symmetrical shape with respect to the through hole 260 and extends to the inner surface 224 of the screw hole 260 and the lower surface of the abutment 200.

The titanium reinforcing member 240 according to the present embodiment is also coupled to the inner surface 224 of the abutment 200 by brazing. Since the brazing method has been described above, a detailed description thereof will be omitted. This titanium zirconia abutment has a long-term stable structure and supports artificial teeth without fracture.

A screw (not shown) is inserted into the fastening hole 260 formed through the center of the abutment 200 and the titanium reinforcing member 240 to couple the abutment 200 to the fixture 280. . A zirconia crown is fabricated on the zirconia abutment, and the crown is bonded onto the zirconia abutment by dental cement in the oral cavity.

3 is a cross-sectional view of a titanium reinforced zirconia abutment 300 by brazing bonding in accordance with another embodiment of the present invention.

Referring to FIG. 3, the titanium-reinforced zirconia abutment 300 by brazing bonding according to the present embodiment is coupled to an internal type fixture 380, a part of which is a fixture 380. ) Is inserted inside. And the abutment 300 according to the present embodiment is a titanium reinforcing member 340 formed by the titanium or titanium alloy therein is coupled by brazing filler metal. In addition, a fastening hole 360 is formed in the center of the abutment 300 and the titanium reinforcing member 340. A screw (not shown) is inserted into the fastening hole 360 to couple the fixture 380 and the abutment 300 to each other. The part inserted into the fixture has a small diameter and a hole is formed in the center, so that there is a thinning part. Therefore, there is a high risk of fracture when fabricating the zirconia. Therefore, this part is made of titanium.

The insertion part 342 of the titanium reinforcing member 340 is inserted into the fixture 380. In addition, some titanium is exposed through the gum, and the Ti exposed to the gum may have a gold or pink color, so it is not an aesthetic problem, and titanium is excellent in biocompatibility. The remaining portion of the titanium reinforcing member 340 is coupled to the inside of the abutment 300 is not exposed to the outside.

The abutment 300 according to the present embodiment is not in contact with the fixture 380 by the titanium reinforcing member 340. As described above, the titanium reinforcing member 340 is in contact with the inner surface 324 of the abutment 300 by the brazing joint surface 330.

Since the screw (not shown) inserted into the fastening hole 360 of the abutment 300 contacts only the titanium reinforcing member 340, the screw (not shown) is formed by zirconia or zirconia alloy by the screw (not shown). It is possible to prevent the abutment 300 from being damaged.

4 is a cross-sectional view of a titanium reinforced zirconia abutment 400 by brazing bonding in accordance with another embodiment of the present invention.

4, the titanium reinforced zirconia abutment 400 by brazing bonding according to the present embodiment is coupled to another type of internal type fixture 480, and therein Titanium reinforcement member 440 is coupled by the brazing joint surface 430. Accordingly, a portion of the inner surface 424 of the abutment 400 and a lower portion of the abutment 400 correspond to the titanium reinforcing member 440 formed by titanium or a titanium alloy.

The insertion portion 442 of the titanium reinforcing member 440 is inserted into the fixture 480. Since the insertion portion 442 has an inclination angle, the insertion portion 442 may be fixed to the fixture 480 by a constant frictional force. In this case, one end of the insertion portion 442 is thin because of the screw hole, so there is a high risk of fracture during fabrication of zirconia. Therefore, this type of abutment emphasizes the need for a titanium reinforcing member. And the remaining portion of the titanium reinforcing member 440 is coupled to the interior of the abutment 400 is not exposed to the outside.

Since the portion of the abutment 400 other than the titanium reinforcing member 440 is formed of zirconia or zirconia alloy, the abutment 400 does not have an aesthetic adverse effect even when exposed to the outside. In addition, a portion of the abutment 400 which is in contact with the screw (not shown) inserted into the fixture 480 and the fastening hole 460 is formed of titanium or a titanium alloy, and thus, the portion of the abutment 400 is connected to the zirconia or zirconia alloy by load. The portion formed by this is not damaged.

5 is a cross-sectional view of a titanium reinforced zirconia abutment 500 by brazing bonding in accordance with another embodiment of the present invention.

5, the titanium reinforced zirconia abutment 500 by brazing bonding according to the present embodiment is coupled to another type of internal type fixture 580, and therein The titanium reinforcing member 540 is coupled by the brazing joint surface 530. Accordingly, a portion of the inner surface 524 of the abutment 500 and a lower portion of the abutment 500 are formed of a titanium reinforcing member 540 formed by titanium or a titanium alloy. This type also emphasizes the necessity of titanium reinforcing members, since all fractures are expected when fabricating zirconia abutments. However, when the titanium reinforcing member is used, the bonding strength between zirconia and titanium becomes a problem, so fracture can be prevented when brazing technology is used rather than general dental cement.

The insertion part 542 of the titanium reinforcing member 540 is inserted into the fixture 580. Since the insertion part 542 has an inclination angle, the insertion part 542 may be stably fixed to the fixture 580. And the remaining portion of the titanium reinforcing member 540 is coupled to the interior of the abutment 500 is not exposed to the outside.

Since portions other than the titanium reinforcing member 540 in the abutment 500 are formed of zirconia or zirconia alloy, the abutment 500 does not have an adverse effect on appearance even when exposed to the outside. In addition, the portion of the abutment 500 that is in contact with the screw (not shown) inserted into the fixture 580 and the fastening hole 560 is formed of titanium or a titanium alloy, and thus, the portion of the abutment 500 is formed of a zirconia or zirconia alloy by a load. The portion formed by this is not damaged.

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 as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

100: titanium reinforced zirconia abutment 120: metal post
128: zirconia abutment 130: brazing filler metal space
140: titanium reinforcing member 160: fastening portion
180: fixture

Claims (18)

Abutments formed by zirconia or zirconia alloys; And
Between the inner surface of the abutment and the fixture, includes a metal reinforcing member formed of a titanium alloy or other bio-friendly alloy,
The metal reinforcing member is a metal reinforced zirconia abutment by brazing bonding coupled to the abutment by brazing. The metal-reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member and the inner surface of the abutment are joined to each other by molten filler metal. The metal-reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member has a frictional cap shape that is frictionally coupled to the friction type post connected to the fixture. The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member has a structure corresponding to an upper portion of the external fixture. The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member has a structure corresponding to the inside of the internal fixture. The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member is made of titanium or a titanium alloy. The metal-reinforced zirconia abutment according to claim 6, wherein the brazing joint uses a filler material including silver (Ag), zirconia (Zr), titanium (Ti), and copper (Cu). The metal-reinforced zirconia abutment by brazing bonding according to claim 6, wherein the filler metal used for brazing bonding has a melting point of 950 ° C or lower. The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member is made of a gold alloy. 10. The metal-reinforced zirconia abutment according to claim 9 wherein the filler metal used for brazing joining comprises gold (Au), silver (Ag), zirconia (Zr) and copper (Cu). The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member is made of a Cr-Co-Mo alloy. 12. The metal reinforced zirconia abutment according to claim 11 wherein the filler metal used for brazing joining comprises silver (Ag), zirconia (Zr), titanium (Ti) and copper (Cu). The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member is a biocompatible metal. The metal reinforced zirconia abutment according to claim 1, wherein a porcelain crown is coupled to the upper portion of the abutment. The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member has a shape connected to correspond to the upper structure of the fixture. The metal reinforced zirconia abutment according to claim 1, wherein the metal reinforcing member has a shape corresponding to the internal structure of the zirconia abutment. The metal reinforced zirconia abutment according to claim 1, wherein a space for filler metal exists between the zirconia abutment and the metal reinforcing member. 15. The metal reinforced zirconia abutment according to claim 14, wherein the space between the zirconia abutment and the metal reinforcing member is 10 to 500 mu m.

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