KR20140062212A - Driver for operating the fixture of an implant - Google Patents

Abstract

The present invention relates to a driver for operating a fixture of a dental implant, in which a lower bonding leg is inserted into a shaft unit of a fixture and mutually combined to the binding groove in a male-female complementary way, wherein the fixture is implanted on the jaw bone, and has a shaft unit at the upper part and the binding groove therein; a polygonal support formed at the upper part of the leg and combined to correspond to the polygonal support side within the upper part of the shaft unit; the fixture is flexibly inserted into the binding leg; and the fixture is moved to an alveolar bone of a patient, and, then, rotates to be operated on the alveolar bone. The driver for operating a fixture of a dental implant according to the present invention comprises a shaft formed in a rod shape; a binding leg projected from the lower part of the shaft and having bonding protrusions mutually combined to a binding groove within the shaft of the fixture in a male-female complementary way; and a polygonal support combined to correspond to the polygonal support side within the upper part of the shaft unit between the shaft and the binding leg. The binding leg is flexibly inserted into the binding groove of the fixture, and the fixture is moved to an alveolar bone of a patient, and, then, rotates to be operated on the alveolar bone.

Description

DRIVER FOR OPERATING THE FIXTURE OF AN IMPLANT [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a screwdriver for implanting a fixture on an alveolar bone of a patient during an implant procedure for forming an artificial tooth, And a lower side fastening leg is inserted into the shaft hole of the fixture formed in the jawbone so as to be coupled to the fastening groove in a complementary manner so that a polygonal support portion is formed on the upper side of the leg, The present invention relates to a screw driver for an artificial tooth fixing device, which is adapted to be fitted to a polygonal support surface so as to elastically fit a fixture on the fastening leg and to move a fixture to a patient's alveolar bone and then rotate the aluminum fixture.

In general, one structure of a driver for an artificial tooth fixing device has a groove formed therein so that a fixture having a mount can be mounted on a lower portion thereof.

As described above, in the conventional screw driver for a fixture having a mount, a head having a square groove formed to be coupled with a mount of a fixture is integrally formed at a lower central portion of the shaft, and a handpiece coupling portion is formed at an upper side thereof have.

A spring insertion groove is formed on both sides of the outer side of the head. A press-fit portion is formed on the outer circumference of an end of the shaft contacting the head. A spring is inserted into the spring insertion groove of the head. Such a conventional driver can easily fix the fixture in which the mount is mounted and place it in the alveolar bone.

However, in the implant procedure, a fixture without a mount may be used. However, such a conventional screwdriver can not be directly used for a fixture without such a mount, and a separate adapter must be used as an intermediary medium. This was a big problem.

In order to solve such a problem, in a conventional "registered driver's model 20-0412097" "driver for a prosthetic dental implant without a mount", a polygonal support part and an elastic body are integrally formed on the head part to fasten the fixture and the driver, And a structure in which the fastening force between the head and the fixed body of the driver is maintained.

However, in the conventional driverless artificial tooth fixing device driver, since the female screw portion is formed inside the shaft hole of the fixing body, the elastic body is caught by the female screw portion to maintain the fastening force, There is a problem in that a good fastening force can not be maintained.

That is, the conventional driver having such a structure can be suitably used for a structure in which the fixture of the implant and the abutment-coupled structure coupled to the upper side thereof are screwed together, but a screw- The combination type fixing body using the fastening protrusion and the fastening groove is made of a useless structure.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a locking device, The present invention relates to a method of implanting a prosthesis of an implant having an abutment which is inserted into the joint groove and is coupled to the joint groove in a complementary manner so that the fixture is easily elastically fitted to the lower side, And then the fixture is rotated so that the fixture can be easily inserted into the alveolar bone, thereby providing a screw driver for an artificial tooth fixator.

In order to accomplish the above object, the present invention provides a driver for implanting a fixture on a alveolar bone of a patient during an implant procedure for forming an artificial tooth,

A rod-shaped shaft;

A fastening leg protruding from a lower side of the shaft and having fastening protrusions complementarily coupled to fastening grooves in the shaft hole of the fixture; And

And a polygonal support portion that is coupled to the polygonal support surface on the inner side of the shaft hole of the fixture body between the shaft and the fastening leg to elastically insert the fastening leg into the fastening groove of the fixture, The present invention provides a driver for an artificial tooth fixing apparatus configured to move the congestion and rotate the congestion to be applied to the alveolar bone.

Preferably, the fastening legs are formed by two or three elongated projections formed on the lower side of the shaft. The fastening legs are bent in a radially inward direction in a process of being elastically fitted and fastened to the fastening grooves of the fastening bodies, And the screw is restored elastically in the radially outward direction so that the fastening protrusions are engaged with the fastening groove and the driver can be pulled out to the upper side freely by the inclined surface.

In order to accomplish the above object, the present invention provides a driver for implanting a fixture on a alveolar bone of a patient during an implant procedure for forming an artificial tooth,

A rod-shaped shaft;

A fastening shaft projecting from a lower side of the shaft and having a resilient repulsion part formed of at least one horizontal through hole and complementarily coupled to the inside of the shaft hole of the fixture; And

And a polygonal support portion which is coupled to the polygonal support surface on the inner side of the shaft hole of the fixture body between the shaft and the fastening shaft so that the fastening axis is elastically fitted in the fastening groove of the fixture body and the fixture is fixed to the alveolar bone of the patient And then rotating the knee joint to rotate the knee joint to perform an operation on the alveolar bone.

Preferably, the fastening shaft is formed with fastening grooves or fastening protrusions on its outer surface, and fastening protrusions or fastening grooves corresponding to each other are formed on the inner surface of the fastening hole of the fastening body to which the fastening axes are coupled, The fastening shaft and the fixture are resiliently coupled to each other when the fastener is coupled to the shaft hole of the fixture.

In the present invention, preferably, the lower end of the fastening shaft forms a closed end of a rod or tube shape, and the horizontal through-hole of the resilient repelling part is formed by a plurality of artificial teeth Provides a driver for stagnation procedures.

Preferably, the fastening shaft is formed in a tapered structure having a reduced sectional area from the upper end to the lower end, and the shaft hole of the fixing body forms an inner circumferential surface of a tapered structure corresponding to the tapered structure of the fastening shaft, Provided is a driver for an artificial tooth fixing operation which facilitates insertion of a fastening shaft into a shaft hole.

In the present invention, preferably, the fastening shafts are formed with auxiliary grooves selectively at the upper, lower, upper, and lower portions of the fastening protrusions or fastening grooves on the outer surface thereof so that when the fastening axis and the fastening body are fastened together, And a screw driver for operating the artificial tooth fixing device.

In addition, the present invention provides a driver for an artificial tooth fixing device, wherein the horizontal through-hole of the elasticity rebounding portion is formed in a rectangular shape, a circular shape, an elliptical shape, or a polygonal shape.

Further, the present invention provides a screw driver for an artificial tooth fixation, wherein the horizontal through hole is filled with an elastic body made of a rubber material.

According to an embodiment of the present invention, there is provided a driver for an artificial tooth fixing apparatus, comprising: a shaft having a rod shape; a shaft projecting from a lower side of the shaft, And a polygonal support which has a fastening leg having fastening protrusions or fastening grooves that are coupled to each other in a complementary manner and which is fitted between the shaft and fastening legs in correspondence with the polygonal support surface of the inside of the shaft hole of the fastening body The fastening leg is elastically fitted in the fastening groove of the fixture, and the fixture is moved to the alveolar bone of the patient and then rotated to perform the operation on the alveolar bone.

According to another embodiment of the present invention, there is provided a screw driver for an artificial tooth fixing device, comprising a resilient repulsion part protruding from a lower side of a shaft instead of the fastening leg and having at least one horizontal through hole, And the fastening shaft is elastically inserted into the fastening groove or fastening protrusion of the fixture so as to move the fixture to the alveolar bone of the patient and then rotate the fastener, .

Therefore, according to the present invention, it is possible to easily and securely fix the fixture on the lower side, and to stably move the fixture on the patient's alveolar bone, and then rotate the fixture to easily perform the operation on the alveolar bone , An improved effect is obtained in which the fixing body and the abutment-joining structure are usefully used in a joining method in which the joining structure is not a screw-joining type but is complementary.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an exploded assembly sectional view showing a driver for an artificial tooth fixing apparatus according to a first embodiment of the present invention; Fig.
2 is an assembled cross-sectional view illustrating a driver for an artificial tooth fixing apparatus according to a first embodiment of the present invention.
FIG. 3A is an exploded assembly sectional view showing a structure of a driver for an artificial tooth fixing device according to a second embodiment of the present invention, in which a fastening groove is formed in the fastening shaft and a fastening protrusion is formed in the fastening member.
FIG. 3B is an assembled cross-sectional view illustrating a structure in which a fastening groove is formed in the fastening shaft and a fastening protrusion is formed in the fastening body in the driver for the artificial tooth fixing device according to the second embodiment of the present invention.
4A is an exploded assembly sectional view showing a structure in which a fastening protrusion is formed in a fastening shaft and a fastening groove is formed in a fastening body in the driver for an artificial tooth fixing device according to a second embodiment of the present invention.
FIG. 4B is an assembled cross-sectional view illustrating a structure in which a fastening protrusion is formed in a fastening shaft and a fastening groove is formed in a fastening body in the driver for an artificial tooth fixing device according to a second embodiment of the present invention.
FIGS. 5A to 5D are cross-sectional views illustrating horizontal through holes of elastic resilience parts of various structures provided in the artificial tooth fixing device driver according to the second embodiment of the present invention.
FIG. 6A is an explanatory view illustrating an operation state in which a fastening groove of a fastening shaft is coupled to a fastening protrusion of a fixture in a driver for an artificial tooth fixing device according to a second embodiment of the present invention. FIG.
FIG. 6B is an explanatory view showing an operation state in which the fastening protrusion of the fastening shaft is engaged with the fastening groove of the fixture in the driver for the artificial tooth fixing apparatus according to the second embodiment of the present invention.
FIGS. 7A and 7B are cross-sectional views of a driver for an artificial tooth fixing device according to a second embodiment of the present invention, in which the fastening shaft has a tapered structure and is coupled to a tapered shaft hole of the fixture.
FIGS. 8A and 8B are views showing a structure of a screw for fixing an artificial tooth according to a second embodiment of the present invention, in which an auxiliary recess is selectively formed in an upper surface, a lower surface, or an upper surface and a lower surface of an outer surface fastening protrusion of a fastening axis, Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

The driver 100 for implanting an artificial tooth fixing apparatus according to the first embodiment of the present invention can be used for implanting a fixture into the alveolar bone of a patient during an implant procedure for forming an artificial tooth A shaft 110 having a rod shape and having a fastening leg 120 at a lower portion of the shaft 110 and a fastening leg 120 coupled to the shaft 110, And a polygonal support portion 130 between the polygonal support portions.

The locking leg 120 protruding from the lower side of the shaft 110 is inserted into the shaft hole 142 of the fixing body 140. In this case, And fastening protrusions 122 that are coupled to the inner fastening grooves 144. [

Such fastening legs 120 are preferably made of a shape memory alloy and can be protruded two or three extensions on the lower side of the shaft 110, as shown in the enlarged AA cross section in Figure 1 . However, it should be understood that the present invention is not limited thereto and may be formed of four or more fastening legs 120.

The fastening protrusions 122 of the fastening legs 120 protrude radially outward from the lower ends of the fastening legs 120 and have a fastening groove 144 formed on the lower side of the shaft hole 142 of the fastening body 140, And is elastically bonded.

That is, when the fastening protrusions 122 of the fastening legs 120 are aligned with the fastening recesses 144 of the fastening body 140 as shown in FIG. 2 The fastening protrusions 122 of the fastening legs 120 are bent radially inward to enter the shaft hole 142 of the fixture 140 and elastically protrude in the fastening groove 144 So that the fastening protrusions 122 are integrally coupled to the fastening groove 144. As shown in Fig.

The fastening protrusion 122 is engaged with the fastening groove 144 of the fixing member 140 and is then pulled out of the fastening groove 144 when the driver 100 is pulled toward the upper side. In other words, the fastening protrusion 122 may be easily slipped off from the fastening groove 144 by forming an inclined surface 123 on the upper surface thereof.

When the fastening protrusion 122 is engaged with the fastening groove 144, the polygonal support 130 formed between the shaft 110 and the fastening leg 120 is inserted into the upper portion of the shaft hole 142 of the fastening body 140 The locking leg 120 is elastically fitted in the locking groove 144 of the fixing member 140 and the fixation member 140 is moved to the alveolar bone of the patient The next rotation can be performed easily on the alveolar bone.

It is also apparent that a fastening groove may be formed on the fastening leg side of the driver and a fastening protrusion may be formed on the fastening groove corresponding to the fastening groove.

When the driver 100 is pulled toward the upper side after the fixture 140 is applied to the alveolar bone of the patient as described above, the engaging protrusion 122 is pulled out of the engaging groove 144 by the inclined surface 123, The abutment (not shown) is complementarily joined to the fixture 140 from which the implant is removed, so that the implant procedure can be continued.

3A and 3B, the driver 200 for implanting an artificial tooth fixing apparatus according to the second embodiment of the present invention includes a shaft 110 having a rod shape, And a resilient repulsion part 170 protruding from the lower side of the fixing member 140 and composed of at least one horizontal through hole 172. The resilient repulsion part 170 is coupled to the inside of the shaft hole 142 of the fixing member 140 in a complementary manner And a polygonal support portion 130 which is coupled to the polygonal support surface 160 inside the upper portion of the shaft hole 142 of the fixture 140 between the shaft 110 and the fastening shaft 180, .

The driver 200 for implanting an artificial tooth fixing device according to the second embodiment of the present invention is characterized in that a coupling groove 182 is formed on the outer surface of the coupling shaft 180 and the coupling shaft 180 is coupled The fastening protrusions 146 are formed on the inner surface of the shaft hole 142 of the fixture 140 so that when the fastening shaft 180 is coupled to the shaft hole 142 of the fixture 140, And the fixing member 140 are resiliently coupled to each other through the coupling groove 182 and the coupling protrusions 146.

4A and 4B, the screw driver 200 according to the second embodiment of the present invention includes a fastening protrusion 184 on the outer surface of the fastening shaft 180, And a coupling groove 148 corresponding to each other is formed on the inner surface of the shaft hole 142 of the fixed body 140 to which the coupling shaft 180 is coupled, The fastening shaft 180 and the fixing body 140 are resiliently coupled to each other through the fastening protrusion 184 and the fastening groove 148. [

The fastening shaft 180 also has a closed end 180a in the form of a bar or tube as shown in Figures 3a, 3b, 4a and 4b, The horizontal through holes 172 of the elasticity rebound unit 170 may be formed in a plurality of equal intervals in the circumferential direction of the fastening shaft 180 in the circumferential direction.

5A, a horizontal through hole 172 of the elasticity rebound unit 170 may be formed in the fastening axis 180. However, as shown in FIG. 5B, Alternatively, as shown in FIGS. 5C and 5D, three or four of the fastening shafts 180 may be formed at regular intervals in the circumferential direction of the fastening shaft 180.

At least one resilient repulsion unit 170 formed of the horizontal through holes 172 is formed on the fastening shaft 180 and the shape of the horizontal through holes 172 is rectangular, circular, elliptical, It is needless to say that they can be variously configured in a polygonal shape.

An elastic body (not shown) made of a rubber material may be additionally filled in the horizontal through hole 172 to function as an elastic means.

The driver 200 for implanting an artificial tooth fixing device according to the second embodiment of the present invention is configured such that the coupling groove 182 of the coupling shaft 180 is engaged with the coupling protrusions 146 of the fixing body 140 The fastening shaft 180 of the fastening body 140 is fastened by the fastening protrusion 146 formed on the inner surface of the shaft hole 142 of the fastening body 140 so that the outer surface of the fastening shaft 180 is elastically rebounded When the fastening groove 182 of the fastening shaft 180 coincides with the fastening protrusions 146 of the fixing member 140, The elastic force is restored and elastically coupled to each other.

6B, when the fastening protrusion 184 of the fastening shaft 180 is elastically fitted in the fastening groove 148 of the fastening body 140, The outer surface of the fixture 140 on the inner surface of the shaft hole 142 of the fixture 140 is flexed inward in the horizontal through hole 172 of the elasticity rebound portion 170 by the engagement projections 184 on the outer surface, When the fastening protrusion 184 of the shaft 180 coincides with the fastening groove 148 of the fixture 140, the accumulated elastic force is restored and elastically coupled to each other.

The polygonal support 130 formed between the shaft 110 and the fastening leg 120 is aligned with the polygonal support surface 160 formed inside the upper portion of the shaft hole 142 of the fixture 140, So that the fastening shaft 180 is elastically inserted into the fixture 140. The fixture 140 can be moved to the alveolar bone of the patient and then rotated to easily perform the operation on the alveolar bone.

When the driver 200 is pulled to the upper side after the fixture 140 is inserted into the alveolar bone of the patient, the coupling groove 182 or the coupling protrusion 184 of the coupling shaft 180 is inserted into the fixture 140 Abutment (not shown) is complementarily joined to the fixture 140 in which the screwdriver 200 is removed and the screw 200 is removed from the fastening protrusion 146 or the fastening groove 148. Thus, As shown in FIG.

7A and 7B, when the fastening shaft 180 is moved from its upper end to its lower end, its sectional area is reduced (reduced) from its upper end to its lower end, as shown in FIGS. 7A and 7B, And the shaft hole 142 of the fixing body 140 may have a tapered inner peripheral surface corresponding to the tapered structure 180b of the fastening shaft 180. [

Since the closed end 180a of the coupling shaft 180 is smaller in diameter than the upper end of the coupling shaft 180 in the tapered coupling structure, the coupling shaft 180 (180) is inserted into the shaft hole 142 of the fixing body 140 Can be more easily inserted.

8A and 8B, the fastening shaft 180 is fastened to the fastening protrusion 184 or the fastening protrusion 184 of the outer surface of the fastening shaft 180. As shown in FIGS. 8A and 8B, in the driver 200 for the artificial tooth fixing apparatus according to the second embodiment of the present invention, Auxiliary grooves 188 are selectively formed in the upper, lower or upper and lower portions of the groove 182 to increase the elastic force of the fastening shaft 180 when the fastening shaft 180 and the fastening body 140 are fastened together. .

That is, the auxiliary grooves 188 of the fastening shaft 180 reduce the cross-section of the fastening shaft 180 at the corresponding portion. Such reduction of the cross-sectional area results in reduction of the section modulus at the auxiliary groove 188 The sectional rigidity is reduced, and consequently the bending deformation of the fastening shaft 180 can be facilitated. The coupling shaft 180 having the auxiliary grooves 188 formed therein may be bent in the radial direction of the coupling shaft 180 rather than the auxiliary groove 188 in the coupling process with the fixing body 140 The fastening shaft 180 and the fixture 140 can be easily attached and detached.

As described above, according to the first and second embodiments of the artificial tooth fixing manipulation driver 100, 200, the fixing body 140 can be easily elastically deformed by the fastening leg 120 or the fastening shaft 180. [ Since the fixture 140 can be stably moved to the alveolar bone of the patient and then the fixture 140 can be rotated to easily apply the fixture 140 to the alveolar bone, It can be usefully used in a coupling method in which the coupling structure is not a screw coupling type but a complementary type.

Although the present invention has been described in detail with reference to specific embodiments thereof with reference to the accompanying drawings, the present invention is not limited to such specific structures. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the following claims. However, it is intended that the present invention covers all such modifications and variations as fall within the true scope of the invention.

100,200: Driver for artificial tooth fixation
110: shaft 120: fastening leg
122: fastening protrusion 123: inclined surface
130: polygonal support 140; Fixed body
142: shaft hole 144: fastening groove
146: fastening protrusion 148: fastening groove
160: polygonal support surface 170:
172: horizontal through hole 180: fastening shaft
180a: closed end portion 180b: tapered structure
182: fastening groove 184: fastening projection
188: auxiliary groove

Claims (9)

1. A driver for implanting a fixture in an alveolar bone of a patient during an implant procedure for forming an artificial tooth,
A rod-shaped shaft;
A fastening protrusion protruding from a lower side of the shaft and having a fastening protrusion or a fastening groove which is complementarily joined to a fastening groove or a fastening protrusion inside the hole of the fastening body; And
And a polygonal support portion that is coupled to the polygonal support surface on the inner side of the shaft hole of the fixture body between the shaft and the fastening leg to elastically insert the fastening leg into the fastening groove or fastening protrusion of the fixture, Wherein the screw is configured to move the fixture to the alveolar bone and then rotate the alveolar bone to perform an operation on the alveolar bone. [3] The apparatus according to claim 1, wherein the fastening legs are protruded from the lower side of the shaft and are protruded and formed, and are bent in a radially inward direction in a process of being elastically fitted in the fastening grooves of the fixture, And the screw is restored to the radially outward direction elastically in the fastening groove so that the fastening protrusions are engaged with the fastening groove and the screwdriver allows the driver to be pulled out to the upper side freely. 1. A driver for implanting a fixture in an alveolar bone of a patient during an implant procedure for forming an artificial tooth,
A rod-shaped shaft;
A fastening shaft projecting from a lower side of the shaft and having a resilient repulsion part formed of at least one horizontal through hole and complementarily coupled to the inside of the shaft hole of the fixture; And
And a polygonal support portion which is coupled to the polygonal support surface on the inner side of the shaft hole of the fixture body between the shaft and the fastening shaft so that the fastening axis is elastically fitted in the fastening groove of the fixture body and the fixture is fixed to the alveolar bone of the patient And then is rotated so as to be performed on the alveolar bone. 4. The apparatus according to claim 3, wherein the fastening shaft has a fastening groove or fastening protrusion formed on its outer surface, and fastening protrusions or fastening grooves corresponding to each other are formed on the inner surface of the fastening hole of the fastening body to which the fastening shaft is coupled, Wherein the fastening shaft and the fixture are resiliently coupled to each other when the fastening shaft and the fixture are coupled to the shaft hole of the fixture shaft. [5] The apparatus as claimed in claim 4, wherein the fastening shaft forms a closed end of a rod or tube shape at the lower end thereof, and a plurality of horizontal through holes of the resilient repelling part are formed at equal intervals in the circumferential direction of the fastening shaft Screwdriver driver. [5] The apparatus according to claim 4, wherein the fastening shaft is formed in a tapered structure having a reduced cross-sectional area from an upper end to a lower end, and the shaft hole of the fixture forms an inner circumferential surface of a tapered structure corresponding to a tapered structure of the fastening shaft, And the insertion of the fastening shaft into the insertion hole is facilitated. [7] The apparatus according to claim 5 or 6, wherein the fastening shaft has an auxiliary groove formed at an upper portion, a lower portion, an upper portion, and a lower portion of a fastening protrusion or a fastening groove on an outer surface thereof, And the elastic force of the fastening shaft is increased. [6] The screw driver as claimed in claim 5, wherein the horizontal through hole of the resilience restraining part has a rectangular, circular, elliptical or polygonal shape. 9. The driver of claim 8, wherein the horizontal through-hole is filled with an elastic material of rubber material.

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