KR102046400B1 - Implant for artificial teeth - Google Patents

Abstract

The present invention relates to an implant for an artificial tooth, capable of suppressing the coupling between parts from being loosened, which comprises: a fixture (100) including a fixture body (101), a lower insert member (102), and an upper insert member (103); an abutment (200); a hollow fixing screw (400) including a head part (420) and a thread part (440); and a core-shaped fixing screw (300) including a head (320), a non-thread stem part (340), and a thread stem part (360).

Description

Implant for artificial teeth

The present invention relates to an implant for artificial teeth, and more particularly, to an implant for artificial teeth including a structure for suppressing the loosening of the fixing screw connecting the fixture and the abutment.

Implants for artificial teeth are implants that are used to implant artificial teeth with the same function as the original teeth by implanting artificial roots made of special metals into the alveolar bone without damaging the surrounding teeth at the site where the teeth are missing.

In artificial tooth implants, loosening of the screws that secure between the abutment and the fixture frequently occurs. Screw loosening can lead to screwing of the screw connections, which can lead to marginal bone absorption or loss of bone adhesion due to deposition of bacterial membranes, screw fractures and overload of adjacent implants.

In addition, external forces or vibrations applied to the implant for artificial teeth cause micromovement between the fixture and the abutment and between the abutment and the fixing screw, and the resulting impact is transmitted to the pubic bone, and also due to the micromovement, The charge force, the force that holds the fixture, is reduced, resulting in loosening of the screw.

Conventionally, a washer or double screw fastening has been used to prevent screw loosening. However, in the related art, there are many limitations in suppressing the screw loosening between the fixture and the abutment. On the other hand, the conventional screw loosening suppression method which suppresses the screw loosening by forcibly eccentric the screw shaft of the fixing screw, such as the wedge method, was used, but there were various problems such as the dismantling of the implant for artificial teeth.

In addition, in the related art, both the fixing screw and the fixture are made of hard materials, and thus the buffer is not easily absorbed between them, and the external screw or the vibration may cause damage due to fine bumps that may occur between the fixing screw and the fixture. It was great.

JP2017-536166 (Published Dec. 07, 2017) Republic of Korea Patent Registration No. 10-1937300 (registered on Jan. 04, 2019) Republic of Korea Patent Publication No. 10-2014-0018674 (published Feb. 13, 2014)

The problem to be solved by the present invention is to provide an implant for artificial teeth comprising a structure for suppressing the loosening of the fixing screw connecting the fixture and the abutment.

An implant for an artificial tooth according to one aspect of the present invention includes a lower vertical hole 1011 and an upper vertical hole 1012 connected to the lower vertical hole 1011 and having a larger cross section than the lower vertical hole 1011. A through-shaped stepped vertical hole is formed in the center and a fixture body 101 having a thread 120 formed on the outer circumferential surface thereof, and is fixed to the lower vertical hole 1011, and has a lower screw fastening hole 1021 at the upper center thereof. A fixture 100 including a formed lower insert member 102 and an upper insert member 103 inserted into and fixed to the upper vertical hole 1012 and having an upper screw fastening hole 1031 formed therethrough; A lower portion consisting of a hollow cone portion 201 converging obliquely downward and a hollow cylindrical portion 202 extending vertically downward starting from a lower end of the hollow cone portion 201 and an upper portion 203 integrally formed above the lower portion; And a through hole including a lower hole 212 and an upper hole 214 having a larger diameter than the lower hole, and having a lower portion inserted into an upper portion of the upper vertical hole 1012. 200; The upper insert through the head portion 420 having the inclined surface and the height maintained by being in close contact with the inclined inner peripheral surface of the abutment 200 in the through hole of the abutment 200 and the lower hole 212 of the abutment 200. A hollow fixing screw 400 integrally including a threaded portion 440 fastened to the upper screw fastening hole 1031 of the member 103; And a threadless stem part 340 and the threadless stem part that extend vertically downward from the head 320 and the head 320 and face a hollow inner surface of the hollow fixing screw 400 without a screw. It is formed in the lower portion of the 340 includes a core-type fixing screw 300 integrally comprising a threaded stem portion 360 is fastened to the lower screw fastening hole 1021 of the lower insert member 102.

According to an embodiment, the lower vertical hole 1011 includes a non-circular cross section, and the lower insert member 102 is inserted into the lower vertical hole 1011 so that the movement in the rotational direction is suppressed. A non-circular cross section in which the upper vertical hole 1012 includes a non-circular cross section, and the upper insert member 103 is fitted into the upper vertical hole 1012 so that movement in the rotational direction is suppressed. And a lower ring groove 1013 is formed at an inner circumferential surface of the lower vertical hole 1011 near the lower end thereof, and a lower stop ring 11 is inserted into the lower ring groove 1013 to insert the lower stop ring 11. By contacting the lower end of the lower insert member 102, the vertical movement of the lower insert member 102 is suppressed, the upper ring groove 1014 is formed on the inner peripheral surface of the upper vertical hole 1012, the upper Ring groove 1014 has an upper portion The stop ring 12 is inserted and the upper stop ring 11 is in contact with the upper end of the upper insert member 103, thereby suppressing the vertical movement of the upper insert member 103.

The implant for artificial teeth according to the present invention can suppress loosening of the coupling between parts. In addition, the implant for artificial teeth according to the present invention has the effect of suppressing the breakage caused by the fine bumps that can occur between the parts.

Many other advantages and effects of the present invention can be understood through the following description of the embodiments.

1 is a cross-sectional view showing an implant for artificial teeth according to an embodiment of the present invention.
2 is a cross-sectional view taken along AA of FIG. 1.
3 is a cross-sectional view taken along BB in FIG. 1.
4a to 4e are views for explaining the assembly process of the implant for artificial teeth.
5 is a cross-sectional view showing an implant for artificial teeth according to another 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.

1 is a cross-sectional view showing an implant for an artificial tooth according to an embodiment of the present invention, Figure 2 is a cross-sectional view taken along A-A of Figure 1, Figure 3 is a cross-sectional view taken along B-B in FIG.

As shown in Figures 1 to 3, the implant for artificial teeth according to an embodiment of the present invention is a fixture 100 embedded in the alveolar bone, abutment 200 to which the artificial teeth are coupled, and the fixture ( It includes a hollow fixing screw 400 for fastening the abutment 200 to 100).

In addition, the dental implant according to the present embodiment may further include a core-type fixing screw 300 that is fastened to the fixture 100 through the inner diameter portion of the hollow fixing screw 400.

For implant treatment, a burial hole should be formed in the alveolar bone. A tool such as a drill is used to form the recess. In addition, the fixture 100 is firmly fixed to the alveolar bone by being screwed into the embedding hole by a screw thread 120 formed on its outer circumferential surface.

In addition, the fixture 100 may include: a fixture body 101 having a stepped vertical hole including a lower vertical hole and an upper vertical hole connected to the lower vertical hole and having a cross section larger than the lower vertical hole; A lower insert member 102 inserted into and fixed in the lower vertical hole and having a lower screw fastening hole formed in the upper center thereof, and an upper insert member 103 inserted and fixed into the upper vertical hole and having an upper screw fastening hole formed in the center thereof in a through type It includes.

The thread 120 is formed on an outer circumferential surface of the fixture body 101. The fixture body 101 is formed of a material having high biocompatibility and high hardness, such as zirconia or Ti, and each of the lower insert member 102 and the upper insert member 103 is easy to process and the fixture Although the hardness is smaller than that of the body 101, the tensile strength is large and may be formed of a material that can withstand impacts well. Furthermore, each of the lower insert member 102 and the upper insert member 103 may be formed of a material having a larger coefficient of thermal expansion than the fixture body 101. For example, the lower insert member 102 and the upper insert member 103 may be formed of a ceramic, metal, or engineering plastic material satisfying the above characteristics.

As mentioned above, the lower vertical hole has a non-circular cross section (preferably, a rectangular cross section), and the lower insert member 102 is inserted into the lower vertical hole so that the movement in the rotational direction is suppressed. Have a cross section; In addition, a lower ring groove is formed at an inner circumferential surface near the lower end of the lower vertical hole, and a lower stop ring 11 is inserted into the lower ring groove to be in contact with the lower end of the lower insert member 102, whereby the lower insert member 102 is formed. The vertical movement of) is also suppressed. The lower stop ring 11 may be made of an elastic ring that can be restored to its original size after being fitted into the upper ring groove in an elastically contracted and deformed state by an external force.

As mentioned above, the upper vertical hole has a non-circular cross section (preferably, a rectangular cross section), and the upper insert member 103 is non-circularly inserted into the upper vertical hole to suppress movement in the rotational direction. Have a cross section; In addition, an upper ring groove is formed on an inner circumferential surface of the upper vertical hole, and an upper stop ring 12 is inserted into the upper ring groove to be in contact with an upper end of the upper insert member 102, whereby the upper insert member 103 of the upper insert member 103 is formed. Up and down movement is also suppressed. The upper stop ring 12 may be made of an elastic ring that can be restored to its original size after being fitted into the upper ring groove in an elastically contracted and deformed state by an external force.

In addition, the abutment 200 has a lower portion and a lower portion composed of a hollow cone portion 201 converging downwardly and a hollow cylindrical portion 202 vertically extending downward starting from a lower end of the hollow cone portion 201. It consists of an upper portion 203 formed integrally. The outer surface of the hollow cone portion 201 is formed as a conical surface converging inclined downward, the outer surface of the hollow cylindrical portion 202 is formed as a straight vertical surface.

As mentioned above, the abutment 200 has a through hole extending in the vertical direction from the top to the bottom in the center. The through hole may include a lower hole allowing the threaded portion 440 to pass through the screwed portion 440 of the hollow fixing screw 400 to be fastened to the upper screwed fastening hole of the upper insert member 103. 212 and an upper hole 214 having a larger diameter than the lower hole.

The hollow fixing screw 400 includes a head portion 420 including an inclined surface 421 and the height of which is maintained by being in close contact with the inclined inner peripheral surface of the abutment 200 in the through hole of the abutment 200; A threaded portion 440 which passes through the lower hole 212 of the abutment 200 and is fastened to an upper screw fastening hole of the upper insert member 103, and between the head portion 420 and the threaded portion 440. It includes integrally the threadless mount 430 formed in.

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 144.

Before the hollow fixing screw 400 is fastened, the upper insert member 103 is cooled to a temperature lower than room temperature by any cooling means, and then the hollow fixing screw 400 is fixed to the upper insert member ( When it is fastened to the upper screw fastening hole of the 103, the upper insert member 103 is thermally expanded at room temperature to be engaged with the hollow fixing screw 400 more freely, thereby, the hollow fixing screw 400 The loosening of can be suppressed.

Meanwhile, the core type fixing screw 300 extends vertically downward from the head 320 and the head 320 by a predetermined length, and has no threadless stem portion facing the hollow inner surface of the hollow fixing screw 400 without a screw thread. 340 and a thread stem portion 360 formed under the threadless stem portion 340 and fastened to the lower screw fastening hole of the lower insert member 102.

 Before the core type fixing screw 300 is fastened, after cooling the lower insert member 102 to a temperature lower than room temperature by any cooling means, the core fixing screw 300 is the lower insert member ( When it is fastened to the lower screw fastening hole of the 102, the lower insert member 102 is thermally expanded at room temperature to be engaged with the core-type fixing screw 300 more freely, thereby, the core-type fixing screw 400 The loosening of can be suppressed.

The fastening between the core-type fixing screw 300 and the fixture 100 to pull the hollow fixing screw 400 further down to minimize the play and to suppress the loosening of the hollow fixing screw 400 through it Do it. In addition, the fastening further provides an anti-loosening effect by double locking.

4a to 4e are views for explaining the assembly process of the implant for artificial teeth. The assembly process of the implant for artificial teeth with reference to Figures 4a to 4e as follows.

As shown in FIG. 4A, a lower vertical hole 1011 of a rectangular cross section and an upper vertical hole 1012 connected to the lower vertical hole 1011 and having a rectangular cross section larger than the lower vertical hole 1011 are included. A fixture body 101 made of Ti or zirconia having a stepped vertical hole is prepared. In this case, a lower ring groove 1013 is formed on an inner circumferential surface of the lower vertical hole 1011 near the lower end, and an upper ring groove 1014 is formed on an inner circumferential surface of the upper vertical hole 1012.

Referring to FIG. 4B, a lower insert member 102 having a rectangular cross section is inserted into and fixed to a lower vertical hole of the fixture body 101. The rotation direction of the lower insert member 102 is achieved by the cross-sectional shape of the lower insert member 102 and the lower vertical hole, and the vertical direction of the lower insert member 102 is a lower stop inserted into the lower ring groove. A ring 11 is achieved by contacting the bottom of the lower insert member 102. A lower screw fastening hole 1021 is formed at the upper center of the lower insert member 102.

Referring to FIG. 4C, the upper insert member 103 having a rectangular cross section is inserted into and fixed to the upper vertical hole of the fixture body 101. The rotational direction fixing of the upper insert member 103 is achieved by the cross-sectional shape of the upper insert member 103 and the upper vertical hole, and the vertical fixing of the upper insert member 103 is an upper stop inserted into the upper ring groove. A ring 12 is achieved by contacting the top of the upper insert member 103. An upper screw fastening hole 1031 is formed at the center of the upper insert member 103.

The fixture 100 is assembled by going through the same process as shown in FIGS. 4A to 4C.

Next, the assembled fixture 100 is fastened and fixed to an implantation hole previously formed in the alveolar bone. The fixing of the fixture 100 may use conventional techniques. When the wrench having a non-circular cross section is inserted into the upper portion of the upper vertical hole without the upper insert member 103 among the upper vertical holes of the fixture body 101, the fixture 100 is inserted into the insertion hole and rotated. The fixture 100 may be fastened to the mounting hole.

Referring to FIG. 4D, a lower portion consisting of a hollow cone portion 201 converging downward and a hollow cylindrical portion 202 extending vertically downward starting from the bottom of the hollow cone portion 201 are integrally formed with the lower portion and the upper portion. A lower portion of the abutment 200 including the formed upper portion 203 is inserted into an upper portion of the through hole of the fixture 100, more specifically, an upper portion of the upper vertical hole of the fixture body 101.

The abutment 200 has a through hole extending in the vertical direction from the top to the bottom thereof at the center. The through hole may include the threaded portion 440 such that the threaded portion 440 (see FIG. 4e) of the hollow fixing screw 400 (see FIG. 4e) described below is fastened to the upper screw fastening hole of the upper insert member 103; A lower hole 212 allowing the passage of the lower hole 212 and an upper hole 214 having a larger diameter than the lower hole.

Next, referring to FIG. 4E, the hollow fixing screw 400 is fastened to the upper insert member 103, thereby fixing between the fixture 100 and the abutment 200. At this time, the threaded portion 440 of the hollow fixing screw 400 is sequentially passed through the upper hole and the lower hole of the abutment 200 is fastened to the upper screw fastening hole of the upper insert member 103. At this time, it is preferable to cool the upper insert member 103 to room temperature or less by using any cooling means just before the fastening of the hollow fixing screw 400.

Referring back to FIG. 1, the threadless stem portion 360 faces the hollow inner surface of the hollow fixing screw 400 while the threadless stem portion 340 faces the lower screw fastening hole of the lower insert member 102. The core fixing screw 300 is fastened to the lower insert member 102 so as to be engaged with the screw.

Before the core type fixing screw 300 is fastened, after cooling the lower insert member 102 to a temperature lower than room temperature by any cooling means, the core fixing screw 300 is the lower insert member ( It is preferable to be fastened to the lower screw fastening hole of 102. The fastening between the core-type fixing screw 300 and the fixture 100 to pull the hollow fixing screw 400 further down to minimize the play and to suppress the loosening of the hollow fixing screw 400 through it Do it. In addition, the fastening further provides an anti-loosening effect by double locking.

5 is a view for explaining the implant for artificial teeth according to another embodiment of the present invention.

Referring to FIG. 5, an annular insertion groove having a predetermined height is formed in a region connecting the lower hole 212 and the upper hole 214 of the inner circumferential surface region of the abutment 200. In addition, the implant for artificial teeth of the present embodiment further includes a viscoelastic support block 500 inserted into the annular insertion groove to viscoelastically support the inclined surface formed on the head portion 120 of the hollow fixing screw 100. The viscoelastic support block 500 is interposed between the hollow fixing screw 100 and the abutment 200 serves to suppress the impact transmitted between them. The viscoelastic support block 500 is formed of a viscoelastic material such as, for example, an elastomer, and has an annular shape, the inclined inner circumferential surface 520 contacting the inclined surface of the head portion 120, and the bottom of the annular insertion groove. It includes integrally the annular insertion protrusion 504 is inserted into the annular groove formed in the. The insertion protrusion 504 may be inserted into the annular groove so that the position of the viscoelastic support block 500 may be more reliably fixed. The inclined inner circumferential surface 520 serves as an inclined surface connecting the vicinity of the upper end of the lower hole 212 of the abutment 200 and the vicinity of the upper end of the upper hole 214 of the abutment 200. The inclined surface formed on the head portion 420 of the hollow fixing screw 400 inserted into the through hole supports the viscoelastic. The viscoelastic support block 500 is pressed by the inclined surface of the head portion 420, and in this compressed state, the inclined inner peripheral surface 520 of the viscoelastic support block 500 is the upper hole of the abutment 200 214) connecting the lower end and the upper end of the lower hole 212 of the abutment 200.

100: fixture 101: fixture body
102: lower insert member 103: upper insert member
200: abutment 300: core type fixing screw
400: hollow fixing screw

Claims (2)

A through-shaped stepped vertical hole including a lower vertical hole 1011 and an upper vertical hole 1012 connected to the lower vertical hole 1011 and having a larger cross section than the lower vertical hole 1011 is formed at the center thereof. A fixture body 101 having a thread 120 formed on an outer circumferential surface thereof, a lower insert member 102 having a lower screw fastening hole 1021 formed at an upper center thereof and fixedly inserted into the lower vertical hole 1011, and the upper vertical portion A fixture 100 inserted into and fixed in the hole 1012 and including an upper insert member 103 formed at a center thereof with an upper screw fastening hole 1031 formed therethrough;
A lower portion consisting of a hollow cone portion 201 converging obliquely downward and a hollow cylindrical portion 202 extending vertically downward starting from a lower end of the hollow cone portion 201 and an upper portion 203 integrally formed above the lower portion; And a through hole including a lower hole 212 and an upper hole 214 having a larger diameter than the lower hole, and having a lower portion inserted into an upper portion of the upper vertical hole 1012. 200;
The upper insert through the head portion 420 having the inclined surface and the height maintained by being in close contact with the inclined inner peripheral surface of the abutment 200 in the through hole of the abutment 200 and the lower hole 212 of the abutment 200. A hollow fixing screw 400 integrally including a threaded portion 440 fastened to the upper screw fastening hole 1031 of the member 103; And
The thread-free stem portion 340 and the screw-free stem portion 340 extending vertically downward from the head 320 and the head 320 and facing the hollow inner surface of the hollow fixing screw 400 without a thread. Is formed in the lower portion of the artificial insert characterized in that it comprises a core-type fixing screw 300 integrally comprising a thread stem portion 360 is fastened to the lower screw fastening hole 1021 of the lower insert member 102 Dental implants. The non-circular cross section of claim 1, wherein the lower vertical hole 1011 includes a non-circular cross section, and the lower insert member 102 is inserted into the lower vertical hole 1011 so that movement in the rotational direction is suppressed. The upper vertical hole 1012 may include a non-circular cross section, and the upper insert member 103 may be inserted into the upper vertical hole 1012 to fit a non-circular cross section in which movement in the rotational direction is suppressed. And a lower ring groove 1013 is formed at an inner circumferential surface near the lower end of the lower vertical hole 1011, and a lower stop ring 11 is inserted into the lower ring groove 1013, so that the lower stop ring 11 is provided. By contacting the lower end of the lower insert member 102, the vertical movement of the lower insert member 102 is suppressed, the upper ring groove 1014 is formed on the inner circumferential surface of the upper vertical hole 1012, the upper ring groove 1014 has an upper part The stop ring 12 is inserted and installed, the upper stop ring 12 is in contact with the upper end of the upper insert member 103, the artificial movement, characterized in that the vertical movement of the upper insert member 103 is suppressed Dental implants.

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