KR102044664B1 - Dental implant system - Google Patents

Abstract

The present invention relates to a dental implant system in which a part of a fixture and a part or all of an abutment are formed of zirconia material, thereby overcoming the problems of an existing metal implant system, while ensuring a strong and secure attachment between the fixture and the abutment. The dental implant system comprises: a fixture (100); an abutment (200) to which an artificial tooth is coupled; and a fixing screw (400) for coupling and fixing the abutment (200) to the fixture (100).

Description

Dental implant system {Dental implant system}

The present invention relates to a dental implant system, and more particularly, by employing a zirconia material in at least a portion of the abutment and the fixture, to overcome the disadvantages of the existing implant system made of metal only More particularly, it relates to a dental implant system capable of ensuring a tight and rigid bond between a fixture and an abutment.

In general, a dental implant system is composed of an abutment that is fastened to the alveolar bone and fixed to the alveolar bone and the abutment supported on the fixture such as an artificial tooth. Most implant systems are metal implant systems using fixtures and abutments made of metal materials such as titanium. However, metal implant systems suffer from the problem that the gum tissue appears black as a shadow due to the natural metal color and opacity.

In contrast, zirconia, which can produce a similar color of artificial teeth and has a translucent property, has been spotlighted as a material of a component constituting an implant system. Zirconia, despite its excellent physical and mechanical properties and excellent biocompatibility, exhibits shrinkage after firing and has a high strength after firing, which makes it difficult to mill, thus making it difficult to apply to the dental field in the past. However, with the development of CAD-CAM technology, it is possible to compensate for shrinkage in the zirconia pore process, which has been widely used in implant systems recently.

The use of zirconia as a prosthetic material has been common, but recently, zirconia is widely used in the manufacture of one-piece or one-body implants in which the part placed in the alveolar bone and the part supporting the artificial tooth are integrated. However, the one-piece implant system made of zirconia has a prosthetic limit as an upper one-piece and has a disadvantage in that it is difficult to remove from the alveolar bone and the load is vulnerable when the implant surgery fails. Zirconia materials may be used as materials for the abutments and fixtures that make up the separate implant system. However, this technique has the following problems or limitations. In other words, when fabricated with zirconia and abutments and fixtures, fully sintered zirconia is difficult to cut, so the semi-sintered zirconia is completely sintered after processing. Causes severe gaps in the various areas between the fixture and the abutment, and these gaps cause loosening of the fixing screw which fastens the fixture and the abutment by external vibration, and furthermore, through the gaps Bacteria will penetrate.

Republic of Korea Patent Registration No. 10-1781087 (Registered September 18, 2017) Republic of Korea Patent Publication No. 10-2019-0087383 (published Jul. 24, 2019) Republic of Korea Patent Publication No. 10-2010-0060828 (published 06.07.2010)

The problem to be solved by the present invention is to form a part of the fixture and all or part of the abutment with zirconia material, overcoming the problems of the existing metal implant system, and yet, between the fixture and the abutment The present invention relates to a dental implant system capable of ensuring a tight coupling.

Dental implant system according to an aspect of the present invention, the fixture 100 is embedded in the alveolar bone; Abutment 200 to which artificial teeth are coupled; And a fixing screw 400 for fastening and fixing the abutment 200 to the fixture 100, wherein the fixture 100 includes at least an external fixture body 140 made of a zirconia material. And a fixture core 120 made of a titanium material and assembled to the fixture body 140, and an outer thread 141 fastened to a buried hole formed in an alveolar bone on an outer circumferential surface of the fixture body 140. ) Is formed, and the fixture body 140 is connected to the upper abutment insertion hole 142 into which the lower part of the abutment 200 is inserted, and connected to the abutment insertion hole 142. And a core insertion hole 145 extending further, wherein a threadless surface is formed on an inner surface of the core insertion hole 145, and a female screw portion for fastening the core is formed on an inner surface of the core insertion hole 145. 1452 is formed, the fixture core 120, the fixed The female screw part is formed on the screw fastening hole 122 formed in the upper center of the fixture core 120 and the lower outer circumferential surface of the fixture core 120 to fasten the threaded portion 440 of the screw 400. 1452, the male screw portion 121 to be fastened, the cone portion 127 protruding in a conical shape from the bottom of the screw fastening hole 122 to the upper side, and the engagement formed in the form of a screw thread on the outer surface of the cone portion 127. It includes a portion (1272), the fixing screw 400, when the threaded portion 440 is gradually lowered while being fastened to the screw fastening hole 122, the cone portion 127 is gradually inserted A recess 442 is provided at a lower end of the threaded portion 440. The recess 442 elastically engages with the engagement portion 1272 in the recess 442 to suppress the retraction of the cone portion 127. An elastic engagement piece 443 is provided.

According to one embodiment, the fixture body 140 is coupled to the outer cylinder portion 1401 and the upper center of the outer cylinder portion 1401, the inclined support member 1402 to define the abutment insertion hole 142 to the inside. And the inclined support member 1402 has an inclined surface in close contact with the cone-shaped lower surface of the abutment 200 inside the abutment insertion hole 142, and the abutment 200 ) Includes an insert member 202 defining a connection hole including an upper hole 214 and an inclined jaw 213 therein, and an upper assembly groove into which the insert member 202 is inserted. Including a butt body 201, the inclined jaw 213 is in close contact with the lower inclined surface of the head portion 420 of the fixing screw 400, the outer cylinder portion 1401 and the abutment body 201 is made of a zirconia material, and the inclined support member 1402 and the insert member 202 are tee It is made of titanium material.

Dental implant system according to another aspect of the present age, the fixture 100 is embedded in the alveolar bone; Abutment 200 to which artificial teeth are coupled; And a fixing screw 400 for fastening and fixing the abutment 200 to the fixture 100, wherein the fixture 100 is formed on an outer circumferential surface thereof and is externally screwed to the alveolar bone 141. And a screw fastening hole 122 formed to fasten the threaded portion 440 of the fixing screw 400, and the upper portion of the abutment 200 is divided into four upper divisions divided by a plurality of incision grooves. 20a, 20b, 20c, and 20d are formed, and in the state where the threaded portion 440 of the fixing screw 400 is fastened to the screw fastening hole 122, resin 20r is formed in the plurality of cutout grooves. It is filled and formed, the resin 20r is in contact with the head portion 420 of the fixing screw 400.

The implant system according to the invention forms part of the fixture and all or part of the abutment with zirconia material, overcoming the problems of the existing metal implant system, while still providing a firm and robust between the fixture and the abutment. It has the advantage of ensuring the coupling.

1 is a cross-sectional view showing a dental implant system according to a first embodiment of the present invention,
2 is an exploded view showing a dental implant system according to a first embodiment of the present invention,
3 is an exploded view illustrating an exploded view of the fixture of the dental implant system shown in FIGS. 1 and 2;
4 is a cross-sectional view showing a dental implant system according to a second embodiment of the present invention,
5 is a cross-sectional view for explaining a dental implant system according to a third embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. It is to be noted that the accompanying drawings and embodiments are simplified and illustrated with the intention of helping those skilled in the art to understand the present invention.

[First Embodiment]

1 is a cross-sectional view showing a dental implant system according to a first embodiment of the present invention, Figure 2 is an exploded view showing a dental implant system according to a first embodiment of the present invention, Figure 3 is a view of Figure 1 and 2 is an exploded view showing an exploded view of the fixture of the dental implant system shown in FIG.

As shown in Figures 1 to 3, the dental implant system according to the first embodiment of the present invention is a fixture 100 that is embedded in the alveolar bone (not shown) and an artificial tooth called a crown is coupled The abutment 200 and a fixing screw 400 for screwing and fixing the abutment 200 to the fixture 100.

For implant treatment, a implantation hole is formed in the alveolar bone using a tool such as a drill. Next, by the external thread 141 formed on the outer circumferential surface of the fixture 100, the fixture 100 is firmly fixed to the alveolar bone by being fastened to the recess.

In the present embodiment, the fixture 100 includes a vertical hole extending a predetermined depth in the vertical direction from the top to the bottom, the vertical hole is the upper cone-shaped the lower portion of the abutment 200 is inserted The butt insertion hole 142 and the abutment insertion hole 142 is connected to extend further down and consists of a screw fastening hole 122 to which the fixing screw 400 is fastened.

In addition, the fixture 100 is a fixture body 140 made of a 3Y-TZP zirconia material and a fixture core 120 made of a titanium material (including titanium alloy) and assembled to the fixture body 140. It consists of.

An outer thread 141 is formed on an outer circumferential surface of the fixture body 140 to be fastened to a buried hole formed in the alveolar bone. In addition, the fixture body 140 includes one hollow extending along a central axis, and the hollow of the fixture body 140 has an upper abutment into which the lower portion of the abutment 200 is inserted. The insertion hole 142 and the abutment insertion hole 142 are connected to the core further extends downwardly includes a hole. A threadless guide surface is formed on the inner surface of the core insertion hole 145, and a female screw portion 1452 for fastening the core is formed on the lower portion of the inner surface of the core insertion hole 145.

As described above, the fixture core 120 is made of titanium and is inserted into the core insertion hole 145 of the fixture body 140 to insert the abutment of the fixture body 140. Located just below the hole 142. The lower part of the core insertion hole 145 of the fixture body 140 is blocked by the insertion of the fixture core 120.

As described above, a screw fastening hole 122 is formed at the upper center of the fixture core 120, and the female screw part 1452 is formed at the lower outer circumferential surface of the fixture core 120. It is provided with a male screw portion 121 to be fastened to. In addition, the fixture core 120 includes a cone portion 127 protruding in a conical shape from the bottom of the screw fastening hole 122 toward the upper side. In the present embodiment, the outer surface of the cone portion 127 is formed with the engaging portion (1272) of the thread or the like. In addition, a wrench hole 1201 into which a wrench for rotating the fixture core 120 is inserted is formed at a lower end of the fixture core 120. Although not shown, a plurality of cutting edges for cutting the alveolar bone may be formed at the lower end of the fixture core 120.

In the present embodiment, the fixture body 140 is manufactured by using the CAD / CAM method, the semi-sintered zirconia molding is manufactured by processing and then completely sintered. Although designed in consideration of shrinkage in the sintering process, it is difficult to mold with high precision. The fixture core 120 is manufactured by a CAD / CAM method according to the shape or dimensions of the pre-fabricated fixture body 140. Because it is made of titanium, it is realized with precise shape or numerical value. The precise shape and dimensions of the thread of the screw fastening hole 122 screwed to the fixing screw 400 is a very important factor in the durability of the implant system and suppressing bacterial invasion. Since the screw fastening holes 122 are formed in the fixture core 120 that can be manufactured in a precise shape, the precision can be increased.

In this case, the fixture body 140 as described above is subjected to surface grinding and sand blasting after complete sintering. Surface grinding performed at a low speed and sand blasting using alumina particles having a small particle diameter may cause surface phase shifting to increase the surface strength of the fixture body 140. In addition, the fixture body 120 may be used to further increase the biocompatibility by coating the hydroxy apatite (HA) on the fully sintered zirconia sintered article.

On the other hand, the abutment 200 is formed of a zirconia material, and includes a cone-shaped lower portion 202 in close contact with the cone-shaped abutment insertion hole 142 that converges downward. The cone-shaped lower surface of the abutment 200 and the cone-shaped inner surface of the abutment insertion hole 142 are preferably in close contact with high precision. In addition, the abutment 200 has a through hole extending in the vertical direction from the upper end to the lower end at the center. The through hole may include a lower hole that allows the threaded portion 440 to pass through the screwed portion 440 so that the threaded portion 440 of the fixing screw 400 will be fastened to the screwed fastening hole 122 of the fixture core 100. 212, an upper hole 214 having a larger diameter than the lower hole 212, and an inclined connecting hole gradually increasing in diameter from an upper end of the lower hole 212 to the upper hole 214. Include. The inclined jaw 213 having an inclined surface is formed in the connection hole.

In addition, when viewed from the occlusal surface, the upper portion of the abutment 200 is divided into four upper divisions 20a, 20b, 20c, and 20d divided into four by four incision grooves 20g arranged at a 90 degree angle. It can be seen that. As such, by widening a portion of the abutment 200, it may contribute to preventing the detachment of the crown. Cement that is usually interposed between the abutment 200 and the crown may lose the function of holding the abutment 200 over time, if the abutment 200 is configured in this way, the above problems In addition to being able to solve the problem, it can also provide an additional effect of reducing the amount of cement used.

The head portion 420 of the fixing screw 400 is located on the lower side of the upper hole 214, the inclined surface of the inclined jaw 213 at the boundary between the upper hole 214 and the lower hole 212 Face to face. In the present embodiment, the upper portion of the upper hole 214 of the abutment 200 remains empty.

The fixing screw 400 connects the head portion 420 having the inclined surface in contact with the inclined jaw 213 formed in the vertical through hole of the abutment 200 and the lower hole 212 of the abutment 200. The threaded portion 440 that is fastened to the screw fastening hole 122 of the fixture core 122 and the threadless portion 430 formed between the head portion 420 and the threaded portion 440 are integrally formed. It includes. A polygonal groove 422 is formed on the upper surface of the head portion 420. The polygon groove 422 may be a groove into which a wrench (not shown) for tightening the fixing screw 400 is inserted when the fixing screw 400 is fastened to the screw fastening hole 122.

As mentioned above, the bottom of the screw fastening hole 122 of the fixture core 120 is a conical (preferably, truncated conical) cone portion 127 is provided with an engaging portion (1272) of a thread or similar form. ) Is formed to protrude. In addition, a conical (frustrated conical) recess 442 converging upward is formed at a lower end of the threaded portion 440 of the fixing screw 400. The recess 442 allows the cone portion 127 to be gradually inserted when the threaded portion 440 of the fixing screw 400 is gradually lowered while being fastened to the screw fastening hole 122. . In addition, the recess 442 is provided with a ring-shaped elastic engagement piece 443 which has a ring shape and elastically engages with the engagement portion 1272 formed in the cone portion 127 to suppress the retreat of the cone portion 127. .

The elastic engagement piece 443 may be installed in a manner of being inserted into a ring-shaped groove formed in the inner wall surface of the recess 442. In this case, the engagement portion 1272 and the elastic engagement piece 443 may be formed in a variety of structures, for example, when the engagement portion 1272 is a screw thread, the elastic engagement piece 443 is the advance of the screw thread. It may be a known anti-loosening washer that permits but prevents the retraction of the thread in the form of a ratchet.

In addition, the shape of the ring-shaped groove and the shape of the elastic engagement piece 443 corresponding thereto may be a polygonal shape that can restrain unwanted rotational movement of the elastic engagement piece 443.

In the above structure, when the screw fastening force of the fixing screw 400 to the screw fastening hole 122 of the fixture core 100 is increased, the male screw portion 121 provided in the fixture core 120 And the tightening tightening force of the female screw portion 1452 provided in the fixture body 140 are further increased, and the engagement between the engaging portion 1272 and the elastic engagement piece 443 is By preventing loosening, after implant surgery, the implant system can be prevented from loosening or shaking against external vibrations.

Second Embodiment

4 is a cross-sectional view showing a dental system according to a second embodiment of the present invention.

As shown in FIG. 4, the dental implant system according to the second embodiment of the present invention has an abutment in which an artificial tooth called a crown and a fixture 100 embedded in an alveolar bone (not shown) are combined. And a fixing screw 400 for screwing and fixing the abutment 200 to the fixture 100.

According to the present embodiment, the fixture 100 includes a fixture body 140 and a fixture core 120 coupled to the hollow lower portion of the fixture body 140 as in the previous embodiment.

Unlike the first embodiment, which is entirely made of zirconia material, the fixture body 140 of the present embodiment has an outer cylinder portion 1401 formed of a zirconia material and a titanium material and is coupled to an upper center of the outer cylinder portion 1401. Being composed of the inclined support member 1402. For example, an adhesive may be used for coupling between the inclined support member 1402 and the outer cylinder portion 1401. The outer cylinder part 1401 is manufactured by using a CAD / CAM method, and is manufactured by completely sintering a semi-sintered zirconia molding after processing. The inclined support member 1402 is manufactured by a CAD / CAM method according to the shape or dimensions of the outer cylinder portion 1401 prepared in advance. Because it is made of titanium, it is realized with precise shape or numerical value. In addition, the outer cylinder portion 1401 may be used to further increase the biocompatibility by coating the hydroxy apatite (HA) on the fully sintered sintered zirconia. The inclined support member 1402 defines a cone-shaped abutment insertion hole 142 therein.

The abutment 200 includes an insert member 202 which defines the upper hole 214 and the connection hole in the vicinity of a connection hole including an upper hole 214 and an inclined jaw 213 thereunder. And an abutment body 201 including an upper assembly groove into which the insert member 202 is inserted. At this time, the abutment body 201 is made of a zirconia material by the CAD / cam method, the insert member 202 is made of a titanium material by the CAD / cam method. Here, the abutment body 201 is first manufactured, and the insert member 202 is manufactured considering the dimensions and shape of the abutment body 201. Adhesive may be used for tighter coupling of the abutment body 201 and the insert member 202.

It is preferable that the inclined jaw 213 facing the inclined surface and the inclined surface of the head portion 420 of the fixing screw 400 is closely adhered to prevent the implant system from loosening or invading the bacteria after the implant surgery. . In the present embodiment, since the insert member 202 including the inclined jaw 213 is made of titanium, the insert member 202 may be implemented in a precise shape and dimensions.

Third Embodiment

5 is a cross-sectional view for explaining a dental implant system according to a third embodiment of the present invention.

As shown in FIG. 5, the dental implant system according to the third embodiment of the present invention, like the previous embodiments, has a fixture 100 embedded in an alveolar bone (not shown), and is referred to as a crown. An abutment 200 to which the artificial tooth is coupled, and a fixing screw 400 for screwing and fixing the abutment 200 to the fixture 100.

For implant treatment, a implantation hole is formed in the alveolar bone using a tool such as a drill. Next, by the external thread 141 formed on the outer circumferential surface of the fixture 100, the fixture 100 is firmly fixed to the alveolar bone by being fastened to the recess.

In the present embodiment, the fixture 100 includes a vertical hole extending a predetermined depth in the vertical direction from the top to the bottom, the vertical hole is the upper cone-shaped the lower portion of the abutment 200 is inserted The butt insertion hole 142 and the abutment insertion hole 142 is connected to extend further down and consists of a screw fastening hole 122 to which the fixing screw 400 is fastened.

In the present embodiment, the fixture 100 may be made of a titanium material (including titanium alloy).

An outer thread 141 is formed on an outer circumferential surface of the fixture 100 to be fastened to a buried hole formed in the alveolar bone. In addition, the fixture body 100 includes a hollow extending in the vertical direction, the hollow is the upper abutment insertion hole 142 and the abutment is inserted into the lower portion of the abutment 200. It includes a screw fastening hole 122 located below the insertion hole 142.

On the other hand, the abutment 200 is formed of a Ti or Ti alloy material, and includes a cone-shaped lower portion 202 in close contact with the cone-shaped abutment insertion hole 142 that converges downward. The cone-shaped lower surface of the abutment 200 and the cone-shaped inner surface of the abutment insertion hole 142 are preferably in close contact with high precision. In addition, the abutment 200 has a through hole extending in the vertical direction from the upper end to the lower end at the center. The through hole may include a lower hole that allows the threaded portion 440 to pass through the screwed portion 440 so that the threaded portion 440 of the fixing screw 400 will be fastened to the screwed fastening hole 122 of the fixture core 100. 212, an upper hole 214 having a larger diameter than the lower hole 212, and an inclined connecting hole gradually increasing in diameter from an upper end of the lower hole 212 to the upper hole 214. Include. The inclined jaw 213 having an inclined surface is formed in the connection hole.

In addition, it can be seen from the occlusal surface that the upper portion of the abutment 200 is divided by a plurality of incision grooves arranged at an angle of 90 degrees, and is formed of a plurality of upper divisions 20a, 20b, 20c, and 20d. Can be. The head portion 420 of the fixing screw 400 is located on the lower side of the upper hole 214, the inclined surface of the inclined jaw 213 at the boundary between the upper hole 214 and the lower hole 212 Face to face. In the present embodiment, the upper portion of the upper hole 214 of the abutment 200 remains empty.

The fixing screw 400 connects the head portion 420 having the inclined surface in contact with the inclined jaw 213 formed in the vertical through hole of the abutment 200 and the lower hole 212 of the abutment 200. The threaded portion 440 that is fastened to the screw fastening hole 122 of the fixture core 122 and the threadless portion 430 formed between the head portion 420 and the threaded portion 440 are integrally formed. It includes. A polygonal groove 422 is formed on the upper surface of the head portion 420. The polygon groove 422 may be a groove into which a wrench (not shown) for tightening the fixing screw 400 is inserted when the fixing screw 400 is fastened to the screw fastening hole 122.

The abutment 200 while the threaded portion 440 of the fixing screw 400 is fastened to the screw fastening hole 142 of the fixture 100 through the vertical through hole of the abutment 200. Resin 20r is filled between the plurality of upper divisions 20a, 20b, 20c, and 20d formed in the upper surface, that is, between 20a and 20b, between 20b and 20c, and between 20c and 20d and 20d and 20a. The resin 20r is in contact with the circumferential surface of the head 420. In addition, the resin 20r is filled between the upper divisions 20a, 20b, 20c, and 20d to be in contact with the head 420. This can greatly contribute to preventing loosening of the fixing screw 400 after the implant system procedure.

100: fixture 200: abutment
400: fixing screw 120: fixture body
140: fixture core 142: abutment insertion hole
145: core insertion hole 127: cone portion
1272: engaging portion 442: recess
443: engagement

Claims (3)

Fixture 100 is embedded in the alveolar bone;
Abutment 200 to which artificial teeth are coupled; And
It includes a fixing screw 400 for fastening the abutment 200 to the fixture 100 by fixing,
The fixture 100 includes at least an external fixture body 140 made of zirconia material and a fixture core 120 made of titanium material and assembled to the fixture body 140.
An outer thread 141 is formed on an outer circumferential surface of the fixture body 140 to be fastened to a buried hole formed in the alveolar bone.
The fixture body 140 has an upper abutment insertion hole 142 into which the lower portion of the abutment 200 is inserted, and a core further extended downward while being connected to the abutment insertion hole 142. Including an insertion hole 145,
A threadless surface is formed on an inner surface of the core insertion hole 145, and a female screw portion 1452 for fastening a core is formed on an inner surface of the core insertion hole 145.
The fixture core 120 includes a screw fastening hole 122 formed at an upper center of the fixture core 120 so that the threaded portion 440 of the fixing screw 400 is fastened to the fixture core 120. A male screw portion 121 formed on a lower outer circumferential surface of the lower portion and fastened to the female screw portion 1452, a cone portion 127 protruding in a conical shape from the bottom of the screw fastening hole 122 toward the upper side, and the cone portion ( An engaging portion 1272 formed in the form of a thread on an outer surface of the 127,
The fixing screw 400 may include a recess 442 that allows the cone portion 127 to be gradually inserted when the screw portion 440 is gradually lowered while being fastened to the screw fastening hole 122. It is included in the lower end of the threaded portion 440, and the inner side of the recess 442 is provided with an elastic engaging piece (443) to elastically engage with the engaging portion (1272) to suppress the retreat of the cone portion (127) Dental implant system, characterized in that. The inclined support member 1402 of claim 1, wherein the fixture body 140 is coupled to an outer cylinder portion 1401 and an upper center of the outer cylinder portion 1401 to define the abutment insertion hole 142 therein. It includes, the inclined support member 1402 has an inclined surface in close contact with the cone-shaped lower surface of the abutment 200 in the abutment insertion hole 142, the abutment 200 An abutment including an insert member 202 defining a connection hole including an upper hole 214 and an inclined jaw 213 therein, and an upper assembly groove into which the insert member 202 is inserted. It includes a garment body 201, the inclined jaw 213 is in close contact with the lower inclined surface of the head portion 420 of the fixing screw 400, the outer cylinder portion 1401 and the abutment body ( 201 is made of a zirconia material, and the inclined support member 1402 and the insert member 202 are tee Dental implant system, characterized in that a material made of titanium.


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