KR101067668B1 - Dental implant assembly having a step for preventing settlement - Google Patents

Abstract

The present invention relates to a dental implant assembly having an anti-sedimentation step so as to prevent subsidence of the abutment due to vertical load due to chewing after implantation of the implant assembly.

According to the present invention, a dental implant assembly is placed in the oral cavity to replace lost teeth, comprising: a fixture embedded in the alveolar bone; Abutment coupled to the fixture to position the prosthesis on the fixture; Anti-sedimentation means for preventing subsidence of the abutment by contacting the fixture upon engagement of the abutment to the fixture; Provided is a dental implant assembly comprising a.

Implants, Fixtures, Abutments, Vertical Loads, Subsidence Prevention

Description

Dental implant assembly with anti-sedimentation step {DENTAL IMPLANT ASSEMBLY HAVING A STEP FOR PREVENTING SETTLEMENT}

The present invention relates to an implant assembly used to recover a lost tooth of a patient, and more particularly to a dental implant having an anti-sedimentation step so as to prevent the abutment subsidence by the vertical load due to chewing after the implant assembly is placed. It relates to an implant assembly for use.

Implant means a substitute that restores lost human tissue. In dentistry, artificial teeth are made by attaching a fixture to the alveolar bone where the natural root has been removed so as to replace the root of the lost tooth. Means a substitute to restore the original function of the tooth.

Such dental implants can be classified in various ways according to the method of coupling the artificial tooth and the root. Among them, there is a screw type implant, which utilizes the bonding force of the screw, and a conventional screw type implant system (implant assembly) is composed of fixtures, abutments, prostheses, and the like.

Fixtures are embedded in the alveolar bone to fix the entire implant system, and are made of titanium with excellent biocompatibility for fusion with human bone tissue. The abutment is coupled to the fixture and serves to fix and support the prosthesis. Prosthetics are produced in the form of teeth through processes such as impression acquisition, work model production, lead production, investment and recall processes.

In general, the implant system configured as described above generally includes a fixture implantation step, an impression acquisition and a work model completion step, a lead production and an inner tube casting step, a prosthetic molding step, and a prosthesis on the exterior of the implant ( It is performed through the prosthesis bonding step of bonding with cement).

1 is a side cross-sectional view of an implant assembly according to the prior art. As shown in FIG. 1, an implant assembly according to the prior art includes a fixture 1 embedded in an alveolar bone, a support column 2 coupled to the fixture 1, and a fixture by the support column 2. It includes the prosthesis (not shown) fixed to (1). The abutment 2 can be fixed to the fixture 1 by means of abutment screws 3 penetrating therein.

According to such a conventional implant assembly, when the abutment 2 is fixed to the fixture 1, the lower periphery inclined surface 6 of the abutment 2 fits with the upper inner periphery inclined surface 5 of the fixture 1. And support the vertical load on the abutment (2).

By the way, as such a conventional vertical load support structure, the abutment 2 may sink and there exists a possibility that an incorrect occlusion problem may arise. In addition, the preload of the abutment screw 3 may be reduced by causing the abutment of the abutment 2 to cause screw loosening.

In the case of using a bridge-type prosthesis in which a plurality of prostheses are connected, if settlement occurs in any one of the plurality of abutments, stress concentration may occur at the prosthetic connection portion, resulting in damage to the prosthesis or fixture.

The present invention for solving the conventional problems, dental implants that form the anti-sedimentation step that can be interlocked with the fixture and the abutment so as to prevent the settlement of the abutment by the vertical load after the implantation of the implant assembly It is to provide an implant assembly.

According to the present invention for achieving the above object, a dental implant assembly to be placed in the oral cavity to replace the missing teeth, a fixture embedded in the alveolar bone; Abutment coupled to the fixture to position the prosthesis on the fixture; Anti-sedimentation means for preventing subsidence of the abutment by contacting the fixture upon engagement of the abutment to the fixture; Provided is a dental implant assembly comprising a.

The anti-sedimentation means preferably includes an anti-sedimentation step formed on the outer circumferential surface of the rent column so as to be caught by the upper inner circumferential edge of the fixture.

The settlement preventing step portion is preferably formed to protrude in an annular convex shape on the outer peripheral surface of the rent.

The anti-sedimentation means is convex at a position corresponding to the anti-sedimentation recess formed in the inner circumferential surface of the fixture, and the anti-sedimentation recessed portion on the outer circumferential surface of the abutment inserted into the fixture. It may include an anti-settling convex portion is formed.

Further, the anti-sedimentation means is concave at a position corresponding to the anti-sedimentation convex portion convexly formed on the inner circumferential surface of the fixture and the anti-sedimentation convex portion on the outer circumferential surface of the rent column inserted into the fixture. It may include a settlement preventing recess formed.

The anti-sedimentation recess is formed in an annular shape, and the anti-sedimentation convex portion is preferably formed in an annular shape or a protrusion shape spaced apart from each other at regular intervals.

The anti-sedimentation means preferably includes an anti-sedimentation bottom surface formed at the lower end of the abutment insert of the fixture so that the lower end of the abutment abuts.

The fixture has an outer circumferential thread formed on the outer circumferential surface to allow insertion and coupling into the alveolar bone, an inner circumferential thread formed under the inner circumferential surface and fastened to the abutment screw, and a lower portion of the abutment formed on the inner circumferential surface. It may include abutment insert having a diameter larger than the inner thread so that it can be inserted.

The abutment may include a through hole formed therein to allow the abutment screw to penetrate, and a lower end having a diameter and a shape that can be inserted into the abutment insert of the fixture.

The abutment insert has a first inclined portion whose inner diameter gradually decreases downwardly from the upper inner circumferential edge of the fixture, and the lower portion of the abutment gradually decreases the outer diameter gradually downward and the It may have a second inclined portion in contact with the first inclined portion when the abutment is coupled.

According to the present invention as described above, the dental implant assembly which has formed the anti-sedimentation step that can be engaged with the fixture and the abutment to prevent the abutment sinking by the vertical load after the implant assembly is placed Can be provided.

According to the dental implant assembly of the present invention, the settlement of the abutment can be prevented by the anti-sedimentation step so that accurate occlusion can be achieved during the use of the implant assembly, and the reduction of the preload of the abutment screw is prevented so that the screw engagement state is achieved. Can be maintained.

In addition, according to the dental implant assembly of the present invention, even when using a bridge-type prosthesis, it is possible to prevent the damage of the prosthesis or fixture by preventing the stress concentration of the prosthetic connection portion due to settlement of some rent.

EMBODIMENT OF THE INVENTION Hereinafter, the dental implant assembly which concerns on preferable embodiment of this invention is demonstrated in detail with reference to drawings.

2 is a side cross-sectional view of an implant assembly according to a first embodiment of the present invention. As shown in FIG. 2, the dental implant assembly according to the first embodiment of the present invention includes a fixture 10 embedded in an alveolar bone and a fix so that a prosthesis can be placed on the fixture 10. And a settlement prevention means capable of preventing settlement of the abutment 20 when the abutment 20 is coupled to the chur 10 and the abutment 20 to the fixture 10. The abutment 20 may be fixed to the fixture 10 by abutment screws 30 penetrating therein.

The fixture 10 includes an outer circumferential thread 11 formed on the outer circumferential surface to enable insertion and coupling into the alveolar bone, and an inner circumferential thread 12 formed below the inner circumferential surface and fastened to the abutment screw 30. It may include an abutment insert 13 formed on the inner circumferential surface and having a larger diameter than the inner circumferential thread 12 so that the lower end portion of the abutment 20 may be inserted.

The abutment insert 13 may have a tapered first inclined portion 14 whose inner diameter gradually decreases downward from the upper inner circumferential edge of the fixture 10.

In addition, the abutment 20 has a through hole 21 formed therein so that the abutment screw 30 can penetrate therebetween, and a corresponding dimension to be inserted into the abutment inserting portion 13 of the fixture 10. It may include a lower end 22 having a diameter and shape.

The abutment lower end 22 may have a tapered second inclined portion 23 in which the outer diameter gradually decreases downward. The second inclined portion 23 may contact each other with the first inclined portion 14 of the fixture 10 when the abutment 20 is coupled to the fixture 10.

In particular, according to the first embodiment of the present invention, as the anti-sedimentation means, the rent base 20 may be provided with an anti-sedimentation step 41 which is caught by the upper inner circumferential edge of the fixture 10. It is preferable that the settlement prevention step part 41 of 1st Embodiment as settlement prevention means protrudes above the 2nd inclination part 23 formed in the lower outer peripheral surface of the abutment 20. As shown in FIG.

The settling prevention step part 41 of 1st Embodiment which protrudes can contact the inner peripheral edge of the upper end of the fixture 10, and can reliably prevent the settling of the abutment 20. As shown in FIG.

The subsidence preventing step 41 may be formed in an annular convex shape on the outer circumferential surface of the abutment 20, or may be formed by protrusions protruding convexly at regular intervals.

3 is a side cross-sectional view of an implant assembly according to a second embodiment of the present invention. The anti-sedimentation means in the implant assembly according to the first embodiment described above includes the anti-sedimentation step portion 41 formed in the abutment 20 so as to be caught by the upper inner circumferential edge of the fixture 10. The anti-sedimentation means in the implant assembly according to the second embodiment includes the anti-sedimentation recess 42 formed in the first inclined portion 14 of the fixture 10 and the second inclined portion of the abutment 20. It is different in that it includes the anti-sedimentation protrusions 43 which are formed convexly at the corresponding positions of 23.

Therefore, in FIG. 3 showing the fixture according to the second embodiment, the same member numbers as those in FIG. 2 are assigned to the same members as those in the first embodiment, and detailed description thereof will be omitted.

In FIG. 3, the anti-sedimentation recesses 42 and the anti-seizure protrusions 43 as anti-sedimentation means are respectively provided on the first inclined portion 14 of the fixture 10 and the second inclined portion 23 of the abutment 20. Although shown as being formed, these anti-sedimentation recessed part 42 and the anti-sedimentation convex part 43 do not necessarily need to be formed in inclination part.

Further, the anti-sedimentation recess 42 is formed in an annular shape on the first inclined portion 14 of the fixture 10, but the anti-sedimentation convex portion 43 is formed on the second inclined portion 23 of the abutment 20. It may be formed in an annular shape, or may be formed in the form of protrusions spaced apart from each other at regular intervals.

In addition, as long as it does not interfere with the insertion of the abutment 20 and the abutment screw 30, as shown in FIG. 4, a settlement preventing convex portion 43 is formed on the inner circumferential surface of the fixture 10 and the outer circumferential surface of the abutment 20. An anti-sedimentation recess 42 may be formed.

5 is a side cross-sectional view of an implant assembly according to a third embodiment of the present invention. The anti-sedimentation means in the implant assembly according to the first embodiment described above includes the anti-sedimentation step portion 41 formed in the abutment 20 so as to be caught by the upper inner circumferential edge of the fixture 10. The anti-sedimentation means in the implant assembly according to the third embodiment comprises an anti-sedimentation bottom surface 44 formed at the lower end of the abutment insert 13 of the fixture 10 so as to catch the lower end of the abutment 20. Is different.

Therefore, in Fig. 5 showing the fixture according to the third embodiment, the same member numbers as those in Fig. 2 are assigned to the same members as those in the first embodiment, and detailed description thereof will be omitted.

Referring to FIG. 5, the lower end of the abutment 20 has a shape inclined toward the outer circumferential side instead of a horizontal plane, and the bottom surface 44 of the fixture 10 also has a shape inclined at the same angle to correspond to the bottom surface 20. Is shown. However, the lower end of the abutment 20 and the anti-sedimentation bottom surface 44 of the fixture 10 may have various shapes other than inclined surfaces or horizontal surfaces as long as they have a shape corresponding to each other.

Hereinafter, with reference to Table 1 and Table 2 will be described the experimental results of comparative analysis of the dental implant assembly according to the present invention and the dental implant assembly according to the prior art.

In Table 1, a static load of the same size is applied to the dental implant assembly according to the first embodiment of the present invention (example) and the dental implant assembly according to the prior art (comparative example) once. The result of comparing the settlement of the posterior landlord and the settlement of the landlord's settlement after applying the same number of repetitive loads (500 times), respectively, are shown.

The dental implant assembly according to the first embodiment of the present invention and the dental implant assembly according to the prior art had the same size, and the applied static load and the repeated load were 500N, respectively.

One 500 N static load
Settlement amount after application (㎛) 500N repeated load 500 times
Settlement amount after application (㎛) Example 1.4 2.4 Comparative example 8.0 12.2

As shown in Table 1, it was found that the dental implant assembly according to the present invention has a significantly smaller settlement than the dental implant assembly according to the prior art even after the static load as well as the repeated load.

In Table 2, loads of the same size are respectively applied to the dental implant assembly (example) according to the first embodiment of the present invention and the dental implant assembly (comparative example) according to the prior art (sink down test). After comparing the torque required to loosen the abutment screw, apply the same frequency (14Hz) and the repeated load of the same size (250N) by the same number of times (10,000 times) (cantilever fatique test A comparison of the landlord's settlement is shown.

Torque amount to loosen abutment screw after settlement test (Ncm) Torque amount (Ncm) to loosen abutment screw after cantilever fatigue test Example 19.0 17.6 Comparative example 9.5 8.2

As shown in Table 2, even after the load is applied to the dental implant assembly according to the present invention it was found that the amount of settling torque to loosen the abutment screw compared to the dental implant assembly according to the prior art is significantly higher.

In other words, according to the dental implant assembly according to the present invention, since the settlement amount is smaller than in the prior art, the preload of the abutment screw does not decrease, and accordingly, the amount of torque required to loosen the abutment screw is not reduced. It can be retained to prevent accidental loosening of the abutment screw.

As described above, the dental implant assembly according to the present invention has been described with reference to the illustrated drawings. However, the present invention is not limited to the embodiments and drawings described above. .

1 is a side cross-sectional view of an implant assembly according to the prior art,

2 is a side cross-sectional view of an implant assembly according to a first embodiment of the present invention,

3 is a side cross-sectional view of an implant assembly according to a second embodiment of the present invention,

4 is a side cross-sectional view of an implant assembly according to a modification of the second embodiment of the invention, and

5 is a side cross-sectional view of an implant assembly according to a third embodiment of the present invention.

Description of the Related Art

10: fixture 11: outer thread

12: inner thread thread 13: abutment insert

14: first inclined portion 20: abutment

21: through hole 22: lower portion

23: second inclined portion 30: abutment screw

41: sinking prevention step 42: sinking prevention recess

43: sinking prevention convex portion 44: sinking prevention bottom

Claims (8)

delete A dental implant assembly placed in the oral cavity to replace a missing tooth, A fixture embedded in the alveolar bone; Abutment coupled to the fixture to position the prosthesis on the fixture; Anti-sedimentation means for preventing subsidence of the abutment by contacting the fixture upon engagement of the abutment to the fixture; Including; And said anti-sedimentation means comprises an anti-sedimentation step formed on the outer circumferential surface of said abutment so as to be caught by the upper inner circumferential edge of said fixture. The method according to claim 2, The subsidence preventing step is a dental implant assembly, characterized in that protruding protruding annularly on the outer peripheral surface of the abutment. A dental implant assembly placed in the oral cavity to replace a missing tooth, A fixture embedded in the alveolar bone; Abutment coupled to the fixture to position the prosthesis on the fixture; Anti-sedimentation means for preventing subsidence of the abutment by contacting the fixture upon engagement of the abutment to the fixture; Including; The anti-sedimentation means is convex at a position corresponding to the anti-sedimentation recess formed in the inner circumferential surface of the fixture, and the anti-sedimentation recessed portion on the outer circumferential surface of the abutment inserted into the fixture. Dental implant assembly comprising an anti-settling convex portion is formed. A dental implant assembly placed in the oral cavity to replace a missing tooth, A fixture embedded in the alveolar bone; Abutment coupled to the fixture to position the prosthesis on the fixture; Anti-sedimentation means for preventing subsidence of the abutment by contacting the fixture upon engagement of the abutment to the fixture; Including; The anti-sedimentation means may be concave at a position corresponding to the anti-sedimentation convex portion convexly formed on the inner circumferential surface of the fixture and the anti-sedimentation convex portion on the outer circumferential surface of the abutment inserted into the fixture. Dental implant assembly comprising an anti-sedimentation recess is formed. A dental implant assembly placed in the oral cavity to replace a missing tooth, A fixture embedded in the alveolar bone; Abutment coupled to the fixture to position the prosthesis on the fixture; Anti-sedimentation means for preventing subsidence of the abutment by contacting the fixture upon engagement of the abutment to the fixture; Including; And said anti-sedimentation means comprises an anti-sedimentation bottom surface formed at the lower end of the abutment insert of the fixture so that the lower end of the abutment abuts. The method according to claim 4 or 5, Wherein the anti-sedimentation recess is formed in an annular shape, and the anti-sedimentation convex portion is formed in an annular shape or a protrusion shape spaced apart from each other at regular intervals. The method according to any one of claims 2 to 6, The fixture has an outer circumferential thread formed on the outer circumferential surface to allow insertion and coupling into the alveolar bone, an inner circumferential thread formed under the inner circumferential surface and fastened to the abutment screw, and a lower portion of the abutment formed on the inner circumferential surface. Includes abutment insert having a diameter larger than the inner circumferential thread so that it can be inserted, The abutment includes a through hole formed therein so that the abutment screw can penetrate, and a lower end having a diameter and a shape that can be inserted into the abutment insert of the fixture. The abutment insert has a first inclined portion whose inner diameter gradually decreases downwardly from the upper inner circumferential edge of the fixture, and the lower portion of the abutment gradually decreases the outer diameter gradually downward and the zone to the fixture. Dental implant assembly characterized in that it has a second inclined portion in contact with the first inclined portion when coupled.

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