KR100483858B1 - Implant - Google Patents

Abstract

The present invention relates to the construction of an artificial tooth (Implant) of the artificial tooth system, and a superstructure coupled thereto, the main object of the invention does not have a hole in the artificial tooth, but rather in the hole on the side of the abutment Forming a post part to be inserted to ensure sufficient strength even in the same diameter, and conversely to have the same strength, but to make the diameter smaller, and blood due to oral fluid or bleeding as usual The purpose of the present invention is to prevent the deterioration of the binding ability remaining in the abutment coupling hole, and further to provide an artificial tooth in the shape of bending the post portion at an arbitrary angle to further expand the range of the procedure.

A characteristic configuration of the present invention for achieving the above object is an artificial tooth system comprising an artificial tooth 10 to be placed in the alveolar bone, abutment tooth 20 to be assembled to the artificial tooth root, and a prosthesis 30 to be assembled to the tooth tooth. In the artificial tooth root 10 is formed in a cylindrical shape, the upper portion of the annular groove 13 formed along the outer circumferential surface, the first tapered portion 14 and the second tapered portion 15 below it The post portion 11 is formed, and the lower portion has an implantation portion 12 which protrudes the disc pins 16 in multiple stages below the post portion 11.

Description

Artificial root of artificial tooth system {Implant}

The present invention relates to an artificial tooth (Implant) of the artificial tooth system, and more particularly, to improve the strength of the artificial tooth by improving the coupling structure with the joint portion (Abutment), the procedure is convenient and conventional screw It is characterized in that it is possible to exclude the combination of the method, and also to exclude the method of coupling the prosthesis and abutment by the existing adhesive (Cement) to be wider to choose according to the patient's dental conditions.

In the artificial tooth system, the artificial tooth is inserted into the alveolar bone and bone fused to the bone, and then the artificial tooth is joined to the abutment which is the support of the artificial tooth, and the prosthesis is applied to the abutment to complete the tooth. It is possible to insert the teeth independently, and thus the artificial teeth can be supported independently so that the intact natural teeth next to the damaged (or extracted) teeth do not need to be shaved, It can be fixed stably and has many advantages, such as long life and superior aesthetics.

The artificial teeth known to date include the external connection method and the internal connection method among the screw methods, and the internal connection in which the screw does not enter at all in the locking taper type among the non-screw methods. It can be divided into (Internal Connection) method.

Screw-type implant system has the disadvantage that the number of parts required is very expensive to manufacture and maintenance, the procedure is complicated, thereby causing a lot of complications, and the cost of transferring to the patient is too expensive.

Most of all, however, screw loosening may occur under any circumstances, and in recent years, there is a tendency to use a deep internal connection method, in which the screw does not loosen well. This is the preferred situation.

In particular, this system is because the coupling between the parts is made by the coupling force of the screw, so the maximum external force that can be supported such as the occlusal force is ultimately dependent on the width of the thread and the width and length of the artificial tooth. This is small and if the bearing capacity is not tolerated, it causes screw loosening and fracture.

In addition, the screw-type implant system is relatively strong in compressive force when performing a functional occlusion function in the oral cavity, but when the pulling force is increased, screw loosening is likely to occur.

In addition, the gap created by poor artificial tooth / butt tooth interconnection becomes a path through which bacteria can enter, causing hygiene problems, and causing inflammation of surrounding tissues and causing alveolar bone to be absorbed.

It is a non-screw implant system that can be seen in FIG. 1 that is invented to compensate for the disadvantages of the screw-type implant system as described above. The locking taper method is essentially based on surface frictional force between the parts. It is by.

However, compared to the screw method, the artificial tooth root (I) used here has a problem that the bonding strength is much higher and there is no problem such as loosening, but the maximum strength of the implant depends on the minimum diameter of the bonding site.

That is, when the abutment A is to be assembled to the artificial tooth I, the post portion A3 of the abutment A is inserted into the hole I2 formed in the center of the artificial tooth I. Therefore, the neck dimension a of the post portion A3 and the edge dimension b of the artificial root I without the neck dimension must be too small.

Therefore, in the case of teeth that require large occlusal force such as molar teeth, it is necessary to select artificial teeth of appropriate thickness and bring the thickness of the posts to a certain width or more. Otherwise, breakage is likely to occur. Is less than 3.5mm, the artificial tooth to be planted in the small area of the oral width, the abutment posts must be thin or the size of the hole of the artificial tooth is the most deadly problem of the conventional implant system This is a problem that needs improvement.

In particular, the minimum diameter of the surrounding bone of the artificial tooth surrounding the artificial tooth after planting the artificial tooth should be about 2.0mm, in the case of FIG. 1 should be at least 7.5mm to secure space for planting. And the narrow space area requires a smaller artificial tooth, no matter how small, the post dimension (A3) of Fig. 1 should not be broken more than 2.0mm, the conventional configuration as described above further reduce the dimensions Due to the unacceptable structure, the range of use is inevitably limited, and if it is made in a smaller size, it tends to be broken, so there is a problem that the use is reluctant.

On the other hand, the implant as described above could not have a form in which the upper end and the lower end bent at any angle.

That is, when placing the artificial root in the alveolar bone, it may be necessary to avoid the anatomical structures of the maxilla or mandible (cortical bones constituting the lower alveolar canal, the perforation, the maxillary sinus) in some cases. Even if the artificial tooth root bent at any angle is inclined to the alveolar bone, the post can rise vertically to the alveolar bone, but the conventional artificial tooth root can form an artificial tooth root shape having a hole in the center thereof. There was no.

Another problem in the related art is whether the screw method or the non-screw method has a hole formed in the artificial root, so that the blood due to oral fluid or bleeding is accumulated during the procedure. It is a problem to halve the binding capacity.

Therefore, the present invention is to solve the problems of the conventional artificial tooth as described above to provide an artificial tooth of a new structure, the main object of the invention does not have a hole in the artificial tooth, but rather relative to the abutment side By forming a post portion that can be inserted into the hole of the same diameter to ensure sufficient strength, and conversely to have the same strength, but to make the diameter smaller, and blood due to oral fluid or bleeding It is to prevent the deterioration of the binding capacity remaining in the abutment coupling hole as in the prior art, and further to provide an artificial tooth in the form of bent the post portion at any angle to further expand the range of the procedure. .

A characteristic constitution of the present invention for achieving the above object is an artificial tooth system comprising an artificial tooth implanted in the alveolar bone, abutment assembled to the artificial tooth, and a prosthesis assembled to the abutment, wherein the artificial tooth is cylindrical Wherein the upper portion is formed in the annulus groove formed along the outer circumferential surface, the first tapered portion and the second tapered portion below the post portion, the lower portion has a mounting portion protruding the multi-stage disc pins below the post portion It is to be.

Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the embodiments and the accompanying drawings.

As is well known, the artificial tooth system includes an artificial tooth 10 placed in the alveolar bone, abutment tooth 20 to be assembled to the artificial tooth root, and a prosthesis 30 to be assembled to the tooth tooth.

The main feature of the artificial tooth root of the present invention is that it does not form a hole (Well) for abutment coupling therein.

In other words, it is formed in a cylindrical shape, the lower part is an implantation part, and a post part is formed on the upper part so that this post part is assembled in the hole 23 formed in the abutment side.

This is the first embodiment of the most basic form shown in Figure 2, the second embodiment shown in Figure 4, the third embodiment can be seen in FIG.

Example 1 (Basic)

The artificial tooth root 10 has an upper portion as a post portion 11 and a lower portion as an implantation portion 12, and the upper post portion 11 has an annular groove 13 formed along the upper outer circumferential surface thereof, It consists of the 1st taper part 14 formed below and the 2nd taper part 15 below it. And the implantation portion 12 to be buried in the alveolar bone is to protrude a multi-stage disc pin (16).

First, the annular groove 13 in the post portion 11 is formed with a width of about 0.3 mm and a depth of about 0.3 mm at a position 0.5 mm downward from the top surface, and when the abutment is assembled thereon, a certain amount of friction occurs. This will help you not to fall out easily.

Moreover, the 1st taper part 14 maintains inclination about 1.5 degrees. That is, since the diameter of the uppermost end with the annular groove 13 is the smallest and becomes thicker downward, when the minimum diameter of the uppermost end is about 2 mm, the diameter immediately before the second tapered portion 15 is about 2.183 mm. do.

The second taper portion 15 is a height section of about 0.5 mm from the first taper portion, the inclination is about 3 degrees, and fits snugly when fitted into the hole 23 of the preparation tooth 20 to be described later. It is to play the role of being fitted.

For reference, about 7 to 8 artificial roots, such as relatively small to large, will be prepared by nominal dimensions.

About seven disc pins 16 are formed in the implantation part 12. The first disc pins 16a of the uppermost layer have a height of 1.3 mm and a diameter of 4 mm, and from below the second disc pins 16b. The intervals to the seventh disc pins 16g are each 1.1 mm.

The maximum diameters of the first disc pins 16a to the fourth disc pins 16d are the same, and the fifth disc pins 16e to 7th disc pins 16g beneath are smaller in diameter. The reason for the smaller diameter is to adhere to follow the contour of the natural tooth, and there is a reason, and the diameter of the lowermost seventh disc pin 16 is about 3 mm.

The upper surface of the first disk pin 16a is an inclined surface of about 45 ° to form an umbrella, and the other second disk pins 16b to seventh disk pins 16g also have an umbrella shape, and the upper surface thereof It consists of a slope of about 20 °.

In addition, the bottom of the bottom of the seventh disc pin (16g) has a convex ridge 17, which is necessary to coincide with the end of the reamer (reamer) used when drilling a hole for artificial tooth in the alveolar bone to eliminate unnecessary alveolar bone This is to reduce the work.

And on the outer circumferential surface of the disc pin 16 can form a vertical uneven groove 18 in the longitudinal direction of the axis and in contact with the cylindrical surface to widen the contact area with the alveolar bone, in this case the seventh disc pin (16g) It is possible to form all from to the second disc pin 16b, because unlike the conventional artificial tooth root (see Fig. 1), since there is no hole inside, even if all of them are formed, the strength is not weakened.

Reference numeral 24 in FIG. 3 denotes a coupling hole, and 31 indicates abutment post.

Example 2 (tilt type)

This is to make the shape of the mounting portion 12 in the same manner as in the first embodiment, and to form the post portion 11 of the upper portion to be inclined at any angle.

In forming inclined, the centerline before tilting and the centerline in the tilted state intersect between the uppermost first disc pin and the tapered portion as shown in FIG. 4.

Since the conventional artificial tooth root (refer FIG. 1) has a hole inside, it cannot be inclined at arbitrary angles and formed.

This causes the post portion 11 to be inclined at about 10 ° to 20 ° with respect to the implantation portion 12, and this angle takes into account the main anatomical structure in the oral cavity. That is, even if the implantation portion 12 is placed in an inclined state to avoid the cortical bone constituting the lower alveolar canal, the hole, the sinus sinus, the post portion 11 is an angle required to maintain the vertical outside the alveolar bone.

In addition, the display portion 11a is formed on one side so that the inclination direction can be understood even when the placing portion is buried.

Example 3 (Micro Type)

As shown in FIG. 5, the hexagonal extension portion 19 is formed between the lower placement portion 12 and the upper post portion 11, and the upper post portion 11 is the same as the previous form, and the lower placement portion 12 has a spiral protrusion 16h.

The cross-sectional shape of the spiral protrusion 16h is trapezoidal, which is appropriate when the inclination angle is about 20 degrees.

Such a micro-type is characterized by reducing the size as a whole, the reason that can be reduced is not to form a hole in the inside, but also to form a post portion 11 on the upper, as described in the actual dimensions in FIG. do.

When the total length is about 13 mm to 14 mm, the post portion 11 has a length of about 3.5 mm, a diameter of about 1.5 mm to 2.0 mm, and the extension portion 19 has a length of about 2 mm, a diameter of about 2.5 mm, and an implantation portion. Reference numeral 12 denotes a length of about 8 mm, a diameter of 1.4 mm and a spiral protrusion 16h of about 2 mm.

Since the size of the expanded portion 19 can be reduced by forming the post portion 11 on the upper portion, the dimension value of 2.5 mm is a data value obtained by several experiments for the minimum diameter. Such a micro-type was virtually impossible to realize in a type of artificial tooth having a hole therein as in the related art, and while using a locking taper method, the cervical portion can operate a small sized tooth.

According to the artificial tooth root of the present invention, since the post portion having the first taper portion and the second taper portion is formed at the top, unlike the conventional method of forming a hole in the artificial tooth root, the support strength is greatly increased when compared to the artificial tooth of the same diameter.

In addition, since the support strength is large, the minimum diameter of the artificial root can be made even smaller as in the microtype of Example 3.

In addition, the post portion can be bent at an arbitrary angle with respect to the implantation portion as in the tilting type of the second embodiment.

Therefore, the artificial tooth root of the present invention has a larger range that can be treated, and the assembling of the prosthesis becomes easier, as well as no accumulation of blood due to oral fluid or bleeding in the course of the procedure. There is an advantage that the ability to halve the ability to prevent, can easily perform a difficult procedure, and because the manufacturing is easy compared to the conventional artificial tooth root has the advantage of providing a low manufacturing cost.

1 is an exemplary view showing a conventional artificial tooth root

Figure 2 is a front view showing the artificial tooth root of the present invention

Figure 3 is a cross-sectional view of the state using the artificial tooth root of the present invention

Figure 4 is a front view showing an artificial tooth root of another form of the present invention

5 is a front view showing an artificial tooth root of another embodiment of the present invention

<Code Description of Main Parts of Drawing>

10: artificial tooth 11: the post portion

12: implantation part 13: hwantehom

14 taper portion 16 disc pin

17: ridge 18: uneven groove

19: hexagonal extension 20: abutment

30: prosthesis

Claims (6)

In an artificial tooth system comprising an artificial tooth 10 placed in an alveolar bone, abutment tooth 20 to be assembled to the artificial tooth, and a prosthesis 30 to be assembled to the tooth tooth, The upper portion of the artificial tooth root 10 is a ring-shaped groove 13 formed along an outer circumferential surface thereof, and a post portion 11 formed of a first taper portion 14 and a second taper portion 15 below. The lower part of the artificial tooth system of the artificial tooth system, characterized in that it has an insertion portion 12 protruding the multi-stage disc pins (16) below the post portion (11). delete The method of claim 1, The artificial tooth root of the artificial tooth system, wherein the post portion 11 is formed in such a state that the axis center thereof is inclined by about 10 ° to 20 ° with respect to the axis center of the insertion part 12. The method of claim 3, wherein The artificial root of the artificial tooth system, characterized in that one side of the post portion 11 is provided with a display portion (11a) so that the inclined direction even in the state where the implantation portion 12 is buried in the alveolar bone. The method of claim 1, The artificial tooth root 10 of the artificial tooth system, characterized in that it is provided with an extension 19 in the middle. The method of claim 1, The extension portion 19 of the artificial tooth root 10 has a diameter of the post portion 11 of 1.5mm to 2.0mm, the maximum diameter of the spiral protrusion 16h of the implantation portion 12 An artificial tooth root of an artificial tooth system, characterized in that when the diameter is 2 mm or less, the maximum diameter is 2.5 mm or less.